Carbohydrate metabolism in Manduca sexta during late larval development

The carbohydrate metabolism in Manduca sexta underwent significant changes during late larval development. Approximately 10% of fat body glycogen phosphorylase was active during the feeding period of the 5th instar, pharate-pupal development and after the pupal moult; it is concluded that glycogen synthesis prevailed. During the last larval and the pupal moult, as well as the wandering stage the percentage of active phosphorylase was significantly increased indicating that fat body glycogen stores were broken down to supply substrates to meet the demands of carbohydrate metabolism. In the course of the last larval moult and the wandering stage the fat body glycogen content decreased significantly from about 300 to about 200 μg mg⁻¹ dry mass substantiating that carbohydrates were released from the fat body. Prior to phosphorylase activation, the concentrations of total haemolymph sugars decreased significantly from about 12 to about 6 mg trehalose equivalents ml⁻¹ (last larval moult) and from about 18 to about 12 mg ml⁻¹ (wandering stage), and increased again slightly when phosphorylase was activated. The haemolymph glucose concentration decreased significantly from about 1.1 to 0.3 mg ml⁻¹ (last larval moult) and in the course of the 5th-instar feeding period from about 1.1 to 0.2 mg ml⁻¹, and remained at this level until the beginning of adult development. The amount of chitosan present in the cuticle increased steadily during the feeding period of the 5th instar from about 10 to 110 mg. It appears that fat body glycogen might be broken down during the last larval moult and the wandering period to provide substrates for chitin synthesis. A dramatic decrease in the amount of chitosan was observed prior to the pupal moult.     

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.     

Temporal events of gypsy moth vitellogenesis and ovarian development

Abstract The vitellogenic period of gypsy moth ovarian development starts on day 3 of the pupal stage and continues through adulthood. During this period, rapid increases occur in follicle size, protein content, and wet weight of the ovary. Patency is observed on day 3 of the pupal stage.
Pre-vitellogenic follicles are formed in the last larval stadium. Newly formed follicles detach from the germarium on day 4, and increase rapidly to 140 per ovariole at the end of the last larval stadium. The pre-vitellogenic follicles are uniformly around 50 um in diameter. No vitellogenin is incorporated into the oocytes until the pupal stage.
Polyacrylamide gel electrophosesis (PAGE) in the presence of sodium dodecylsulphate (SDS) analysis of male and female haemolymph samples and vitellogenic ovaries demonstrates the presence of two female-specific subunits of vitellogenin of 180 kD and 160 kD. These proteins are detected only in haemolymph and ovarian extracts of vitellogenic females. The molecular weight of the native protein determined by size exclusion chromatography is approximately 400–420 kD.
A highly sensitive double antibody sandwich enzyme-linked immunosorbent assay (ELISA) was developed to monitor the temporal changes in vitellogenin titre in haemolymph. Vitellogenin production starts on day 2 of the last larval stadium, reaching a maximum level by day 6 of the last larval stadium, and decreasing in the late pupal stage as vitellogenin was internalized into the oocytes. This is the first report of vitellogenin production occurring in the larval stage of a holometabolous insect. The fact that vitellogenin production and uptake occur during different stages of development in the gypsy moth, opens up some interesting questions concerning the underlying regulatory mechanisms controlling each process.     

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.     

Changes taking place in the electrophoretic haemolymph protein pattern during metamorphosis of Polytela gloriosae (Lepidoptera)

The haemolymph proteins of the larva, pupa and adult of Polytela gloriosae have been fractioned by Polyacrylamide gel disc electrophoresis. In the haemolymph of the fifth instar larval stage a total of ten protein fractions have been detected. The concentration of the protein fractions 2, 3, 4, 9 and 10 shows oscillations in their concentration in the early fifth instar, middle fifth instar and late fifth instar larval stage. In all 11 protein fractionswere detected in the haemolymph of different stages of the pupa. The protein bands 1, 7 and 10 of the pupa appear newly in the haemolymph as these bands were not found in the haemolymph of the larvae. The protein fraction 9 of larva was not found in the pupa. In the haemolymph of adult insect sexual difference was observed in the haemolymph protein pattern. In the haemolymph of adult female a total of 10 protein fractions were detected while from the male haemolymph a total of 8 protein fractions were detected. The pupal band 7 was not found in the adults of both the sexes. In the haemolymph of larva and adult one pigmented protein fraction was observed. No pigmented protein fraction was found in the haemolymph of pupa. Iron - containing protein fraction and the acid mucopolysaccharides were not found in the haemolymph. The protein fractions 3, 4, 5, 6 and 7 of adult haemolymph were darkly stained by the Schiff reagent and, thus, they are the fractions of glycoprotein. One protein fraction of lipoprotein was also found in the haemolymph.     

Development and feeding behavior of <Emphasis Type="Italic">Helicoverpa armigera</Emphasis> (Hübner) (Lepidoptera: Noctuidae) on different sunflower genotypes under laboratory conditions

The aim of this study was to assess the biological aspects and food preferences of Helicoverpa armigera fed different sunflower genotypes and an artificial diet. Tests were performed under multiple-choice and no-choice conditions to evaluate the biological characteristics of H. armigera. In addition, the biological data obtained were used to determine parameters of fertility life tables. The results showed that H. armigera does not have a feeding preference among the sunflower genotypes tested. The larval period on sunflower ranged from 15.0 to 16.2 days. The maximum fecundity on sunflower was 542.6 eggs/female and that on the artificial diet was 794.5 eggs/female. In general, insects feeding on Helio 250 consumed greater quantities of leaves, had higher survival until the end of the pupal stage, displayed high population growth rates, and had low population doubling times, suggesting that in the field populations will achieve greater population densities when fed on Helio 250. Insects that fed on CF101 consumed smaller leaf areas, had lower survival until the end of the pupal stage, lower fertility rates, and lower population growth rates, and may also have displayed lower population densities and smaller reductions in field productivity. This insect developed best on an artificial diet in comparison to sunflower genotypes studied.     

Induction of perfect superlarvae by the application of juvenile hormone analogue to starved larvae of the silkworm,Bombyx mori

Topical application of juvenile hormone analogue, methoprene, induced a supernumerary larval moult in the silkworm, Bombyx mori. The incidence changed greatly depending on developmental stages and physiological states of the methoprene-treated larvae. When methoprene was applied to feeding larvae, only those treatments from the middle of the 2nd instar until the middle of the 4th instar were effective. An 18-h starvation period from the beginning of the 4th instar and a dose of 1 μg of methoprene per larva were required for 100% incidence of the perfect superlarvae. Allatectomy had no effects on the induction of superlarvae by methoprene. The treated 4th-instar larvae ecdysed to the 5th instar without any delay compared to the controls, and underwent an additional larval ecdysis 4.5 days later. The induced 6th-instar larvae took 8.5 days until the onset of cocoon spinning. The induced superlarvae showed reduced growth rates but an increase of final mass due to prolonged feeding period. A sharp but reduced peak in ecdysteroid titre in the haemolymph appeared one and a half days prior to each larval ecdysis in the treated larvae, suggesting that methoprene provokes the extra larval moult through an additional release of ecdysteroids.     

Juvenile hormone-specific esterases in the haemolymph of the tobacco hornworm, Manduca sexta

A new sensitive method for determining juvenile hormone (JH) hydrolysis has been developed which measures the release of tritiated methanol from JH labelled in the methyl ester group. Using this assay we investigated the interaction of JH with haemolymph esterases and haemolymph JH-binding protein. Haemolymph from fifth instar larvae of Manduca sexta contains two families of esterases which can be distinguished by their reactivity with diisopropylphosphorofluoridate (DFP). One group consists of general esterases which are capable of hydrolysing free JH but not JH complexed to the binding protein and are completely inhibited by low concentrations of DFP (10⁻⁴ M). The other group (JH-specific esterases), relatively DFP resistant, has little detectable general esterase activity but can hydrolyse JH bound to the binding protein as well as free JH. The major JH-esterase has a sedimentation coefficient of 4·98 S and a diffusion coefficient of 6·4 × 10⁻⁷ cm² sec⁻¹. The molecular weight calculated from these values is 6·7 × 10⁴. The general esterases are present throughout the larval stage, but the JH-specific esterases are barely detectable until the fourth day of the fifth instar when they suddenly appear at a high concentration. Since the general esterases cannot hydrolyse bound JH, one function of the binding protein is to protect JH during transport in the early instars, thus confirming that the binding protein is a true carrier of JH. In the late fifth instar prior to metamorphosis, however, JH-specific esterases appear in the haemolymph resulting in the hydrolysis of JH complexed to the carrier protein. Thus, by lowering JH titre, the JH-esterases play an important rôle in development in M. sexta.     

Côntrole neuroendocrine des protéines sanguines vitellogenes d'Anacridium aegyptium sain et parasite

The changing patterns of haemolymph proteins were followed in male and female adults of normal and parasitized Anacridium aegyptium during diapause (autumn, winter) or during activity (spring) of their endocrine system without or with electrostimulations of the pars intercerebralis (PI).The haemolymph protein concentration is high in winter and decreases in spring. It is comparatively depleted in locusts infected by the fly Metacemyia calloti. However, the depletion is significant only in ‘castrated’ females.Fifteen protein fractions were resolved by polyacrylamide disk gel electrophoresis in haemolymph of normal and infected locusts during diapause and activity. Some fractions decrease in quantity during activity in males, normal females, and parasitized females with complete ovarian development. One fraction disappears in females with mature eggs and seems correlated with formation of the eggshell. Eight others protein fractions exhibit electrophoretic mobility identical to the 7 protein fractions of homogenates of eggs. There is little doubt that these haemolymph protein fractions are involved in yolk synthesis and are thus ‘vitellogenic’. One of these ‘vitellogenic’ fractions (band 6) is larger in yolk than in blood.Five protein fractions were demonstrated by electrophoresis of homogenates of parasites. Their electrophoretic mobilities are similar to those of 5 of the 8 haemolymph ‘vitellogenic’ fractions of the host. There is little doubt that these 5 haemolymph protein fractions (one of them is the band 6) are involved in the nutritional requirements of the parasite.Electrostimulation of the PI, during diapause and activity, increase the haemolymph protein concentration and chiefly the protein concentration of the blood band 6. Thus, the median neurosecretory cells of the brain (M-NSC) regulate protein synthesis and chiefly the synthesis of ‘vitellogenic’ proteins.In parasitized females, the increase of the haemolymph protein concentration after electrostimulations of the PI is associated with an enhancement of ovarian development. The depletion of the haemolymph protein concentration in ‘castrated’ females is thus involved in the inability of the oöcytes to sequester available proteins from the haemolymph. The haemolymph protein deficiency may be attributed to (1) an impairment of protein synthesis, attendant upon the hypoactivity of the M-NSC, and (2) the nutritional requirements of the parasite.     

Major haemolymph proteins inCeratitis capitata: Biosynthesis and secretion during development

Summary The accumulation of major haemolymph proteins (a group of proteins immunologically related to Calliphorin) their biosynthesis in vivo and in organ culture as well as their secretion, has been studied during the late larval stages and white pupae of the Mediterranean fruit flyCeratitis capitata. The accumulation of major haemolymph proteins in the haemolymph, shows a twenty fold increase from the 4-day old larvae to the white pupae stage, while in the fat body there is only a seven fold increase. It is evident from the in vivo and organ culture studies, that the major haemolymph proteins are synthesized during the late larval stage and their synthesis declines abruptly during the stage of white pupae. It seems also that each polypeptide has its own characteristic developmental kinetics of synthesis. The major haemolymph proteins are synthesized in the fat body and are very quickly secreted into the haemolymph.     

Feeding causes the appearance of a factor in the haemolymph that stimulates protein synthesis

Soon after a locust (Locusta migratoria) begins to feed, an increase in protein synthesis can be detected in the animal. Isolation of fat body shows that this tissue synthesizes protein at a faster rate in recently fed animals than it does in fasting insects. Fasting locusts injected with haemolymph from fed insects increased protein synthesis when compared with locusts injected with haemolymph from fasting locusts. The factor causing this increase was present in the haemolymph within 5 min of feeding. Feeding or direct contact with the food was not essential to increase protein synthesis. Exposure of fasting locusts to feeding insects was sufficient to elevate the rates of protein synthesis in the fasting animals.The increase inprotein synthesis was not a result of general excitation or an increase in the concentration of tryptophan or isoleucine in the haemolymph. Ecdysteroid titres were uniformly low during the first ten days of adult life. Gel filtration of the fed haemolymph revealed a low molecular weight fraction (about 600 daltons) which stimulated protein synthesis upon injection into fasting locusts.     

Changes in vitellin and other yolk proteins during embryonic development in the silkworm, Bombyx mori

Changes in the amounts of vitellin and other yolk proteins of the eggs of the silkworm, Bombyx mori were investigated during embryonic development using polyacrylamide gel electrophoresis and immunotitration techniques. In the newly laid eggs, soluble proteins were separated into at least nine bands after electrophoresis. The major band was identified as vitellin, accounting for about 40% of the total proteins. The four predominant bands including vitellin exhibited the same mobility as the proteins of haemolymph, but one other major band was specific to the eggs, accounting for about 20% of the proteins.During embryonic differentiation 6–7 days after oviposition, the total protein content did not decrease and the banding patterns and their relative concentrations remained unchanged as a whole. However the concentration of the egg specific protein steadily decreased. During subsequent larval differentiation until hatching, the total proteins were utilized to about 50% of the initial levels: the rapid degradation was observed in almost every species of proteins.An immunotitration experiment further demonstrated that vitellin was not utlilized during embryonic differentiation but was consumed markedly during larval differentiation. However, about 30% of initial level was reserved in the newly hatched larvae. Such a prolonged persistence of vitellin is discussed in relation to protein metabolism during embryonic development in silkworms.     

Ontogeny of protein concentration,haemocyte concentration and antimicrobial activity against Escherichia coli in haemolymph of the invasive harlequin ladybird Harmonia axyridis (Coleoptera: Coccinellidae)

The harlequin ladybird is considered to be one of the most successful invasive insect species. Among other traits, its invasive success is considered to be caused by a powerful immune system. In the present study, we investigate the ontogenetic profile of protein concentration, concentration of circulating haemocytes and constitutive antimicrobial activity against Escherichia coli in Harmonia axyridis haemolymph during late larval development and early adult life. Protein concentration increases during the first 32 days of adult life from 45 to 100 mg per mL of haemolymph and reaches intermediate values during larval stages. The concentration of circulating haemocytes is very low (5000 haemocytes per μL of haemolymph) in late larval stages and increases strongly during first 8 days of adult life to values of approximately 30 000 haemocytes per μL of haemolymph. The killing efficiency of haemolymph against E. coli is lowest in larval stages, rapidly increases in the prepupal stage and then steadily grows during the whole period of adult life. There are no significant effects of sex on any of the investigated physiological or immune parameters. In general, the patterns observed for H. axyridis contrast with many results that are reported for other insects (e.g. bees, fruit flies, crickets or mosquitoes). One possible explanation is the contrasting life history of H. axyridis, with a fast preimaginal development and a long adult lifespan being linked to a long reproductive period. Substantial variation in physiological and immune parameters during ontogeny also has important methodological implications because individuals of exactly the same stage/age have to be employed for comparative studies.     

Utilization of U-14C amino acids or U-14C protein by adult Glossina morsitans during in utero development of larva

Administration of U¹⁴C protein hydrolysate in the diet of adult female Glossina morsitans at different times throughout the second reproductive cycle was followed by analysis of the distribution of radioactivity between the adult flies, their excreta, and the fully grown third instar larvae produced by these flies. A constant proportion of the total administered label was recoverable independently of the time lapse between administration and assay. Peak incorporation of labelled material occurred in the larva between the seventh and eighth day of a 9 or 10 day interlarval period, indicating that the larva feeds avidly on recently synthesized maternal uterine gland secretion at this time. Haemocoelic injection of U¹⁴C protein hydrolysate into similar adult females, between feeds, resulted in continued incorporation of labelled material by the larva to within 12 hr of parturition. Results are consistent with the hypothesis that uterine gland secretion and larval feeding continue throughout the intrauterine life of the larva.A constant and low proportion of detectable label remained in the adult fly while increased incorporation by the larva was paralleled by a reduction of detectable label in the adult excreta. This indicates direct competition between the uterine gland cells and those of the Malpighian tubules for free amino acids in the haemolymph.Administration of U¹⁴C protein in the adult diet did not result in incorporation of label by the developing larva, and the bulk was excreted as protein by the adult fly. Apparently the midgut trypsin of G. morsitans is incapable of splitting this labelled protein.Analysis of urine and haemolymph samples from flies in early pregnancy, recently fed on a diet containing U¹⁴C protein hydrolysate or U¹⁴C protein, shows that free labelled amino acids in the diet enter the adult haemolymph almost immediately after feeding, and are excreted along with dietary water during initial diuresis. The labelled protein used in these experiments was not taken up by the haemolymph and consequently did not appear in the urine.Implications are that the adult female G. morsitans possesses little storage capacity for substances in the diet which are destined to provide nutrients for the developing larva. Assuming a 48 hr digestion time, the digestive products of a blood meal ingested on day 5 or 6 of a 9 day interlarval period will provide the bulk of nutrients for larval growth. It is therefore significant that blood meals ingested at this time are larger than those ingested earlier or later in the cycle.     

Adipokinetic hormone-induced lipid mobilization and lipophorin interconversions in fifth larval instar locusts

The response of fifth larval instar locusts to injected adipokinetic hormone (AKH) is only poor, as is reflected in both a very moderate elevation of the haemolymph lipid concentration and the slight occurrence of the haemolymph lipophorin interconversions characteristic for adult locusts, resulting in formation of only small quantities of the low density lipophorin (A⁺). However, an additional lipophorin fraction (A′) is induced, which is intermediate in density and size between high and low density lipophorin and which is not identified in adult haemolymph. As in adults, larval A⁺ formation includes association of the resting high density lipophorin with a non-lipid containing protein (C₂), the haemolymph concentration of which is only one-fifth relative to adults. However, the larval haemolymph protein composition is not the primary cause of the incomplete adipokinetic response, as elevation of the concentration of protein C₂ by injection of isolated adult C₂, whether or not in combination with adult high density lipophorin, did not increase lipophorin conversions nor haemolymph lipid elevation.In vitro incubation of larval fat bodies in adult haemolymph showed that competency to both the AKH-induced lipid release and the haemolymph lipophorin conversions of the larval fat body are reduced compared to equal amounts of adult tissue. Reciprocal incubation of adult fat body in larval haemolymph resulted in only a very moderate adipokinetic response, demonstrating that larval haemolymph protein composition is restrictive for full development of hormone action.Both immunoblotting experiments and enzyme-linked immunosorbent assays (ELISA), using monoclonal antibodies specific for the adult lipophorin apoproteins, indicated that the larval lipophorins closely resemble the adult forms. Apparently the structure of locust lipophorins is remarkably constant throughout development despite changes in metabolic functions.     

Effect of allatectomy on ecdysteroid-dependent development of Rhodnius prolixus larvae

the regulation of haemolymph titres of ecdysteroids during larval development of the bloodsucking bug, Rhodnius prolixus was studied. Corpus allatum ablation in 4th-instar larvae 1 day after feeding was reflected in an increase of the intermoult period and in a high level of ecdysial arrest. These effects could be corrected by juvenile hormone and ecdysone therapies. Comparison of the ecdysteroid titres in haemolymph determined in control and allatectomized larvae, at different intervals after feeding, showed that allatectomy drastically depressed the ecdysteroid levels. Juvenile hormone treatment reestablished ecdysteroid titres in the haemolymph of allatectomized insects. Isolated prothoracic glands from allatectomized larvae had a very low production of ecdysteroid-RIA-activity when compared with prothoracic glands from control or allatectomized larvae which received in vivo juvenile hormone treatment. The complexity of the corpus allatum-prothoracic glands interaction in Rhodnius post-embryonic development is discussed.     

Egg size and the evolution of phenotypic plasticity in larvae of the echinoid genus Strongylocentrotus

Planktotrophic larvae grow by utilizing energy obtained from food gathered in the plankton. Morphological plasticity of feeding structures has been demonstrated in multiple phyla, in which food-limited larvae increase feeding structure size to increase feeding rates. However, before larvae can feed exogenously they depend largely on material contained within the egg to build larval structures and to fuel larval metabolism. Thus, the capacity for plasticity of feeding structures early in development may depend on egg size. Using the congeneric sea urchins Strongylocentrotus franciscanus and S. purpuratus, which differ in egg volume by 5-fold, I tested whether the degree of expression of feeding structure (larval arm length) plasticity is correlated with differences in the size of the egg. I experimentally manipulated egg size of S. franciscanus (the larger-egged species) by separating blastomeres at the 2-cell stage to produce half-sized larvae. I reared half-size and normal-size larvae under high and low food treatments for 20 days. I measured arm and body lengths at multiple ages during development and calculated the degree of plasticity expressed by larvae from all treatments. Control and unmanipulated S. franciscanus larvae (from ∼ 1.0 nl eggs) had significantly longer arms relative to body size and a significantly greater degree of plasticity than half-sized S. franciscanus larvae (from < 0.18 nl eggs), which in turn expressed a significantly greater degree of plasticity than S. purpuratus larvae (from ∼ 0.3 nl eggs). These results indicate that egg size affects larval arm length plasticity in the genus Strongylocentrotus; larger eggs produce more-plastic larvae both in an experimental and a comparative context. However, changes in egg size alone are not sufficient to account for evolved differences in the pattern of plasticity expressed by each species over time and may not be sufficient for the evolutionary transition from feeding to non-feeding.     

The relationship between nutrition,vitellogenin, vitellin and ovarian development in the housefly, Musca domestica L.

The effect of adult nutrition on oögenesis during the first gonotropic cycle was studied in three strains of the housefly, Musca domestica. Two of the strains were anautogenous and the third was autogenous. In these strains, three subunits (51, 43 and 42 kdaltons) of vitellogenin and vitellin were electrophoretically identical using SDS-PAGE electrophoresis for haemolymph proteins of vitellogenic females and for egg extracts. Each developmental stage of the ovary in individual females flies of both autogenous and anautogenous strains fed on either sugar or protein clearly reflected the appearance of electrophoretic bands for vitellogenin and vitellin. Using immunological analysis, a very small amount of vitellogenin was detectable in the haemolymph of previtellogenic flies. The highest level of vitellogenin appeared in the haemolymph at the middle of vitellogenic phase and reached about 25% of the total haemolymph protein. There were differences in vitellogenin concentration in females with mature eggs between the two anautogenous strains: vitellogenin was not detectable in one strain, and the other showed 30% of the maximal level.     

Änderungen im muster der Haemolymphproteine von adulten Königinnen der Hummelart Bombus terrestris

The soluble proteins of haemolymph during the life cycle from adult bumblebee queens (Bombus terrestris) were separated by disk electrophoresis on polyacrylamide gels. Twenty-three fractions stainable with amido black were detected. Every phase of the bee's adult life is characterized by a specific pattern of haemolymph proteins.Newly emerged queens have a low haemolymph protein concentration which increases in the first 5 days to a maximum. The high concentration is probably connected with the synthesis of hibernation reserves. Before the beginning of hibernation the concentration of some protein fractions seems to decrease; the concentration of these fractions is low also after hibernation.During the spring the first oöcytes begin to grow and the activity of corpora allata, hypopharyngeal glands, and wax glands reaches a maximum at the time of starting nests. A large increase in the concentration of haemolymph proteins is correlated with the activity of these glands. This high concentration does not change during the whole egg-laying period; however, the concentration decreases to a minimum in old queens with degenerating ovaries.In the protein pattern of ovary homogenate we detected three fractions with an RF identical to haemolymph fractions. Investigations on queens parasitized with the nematode Sphaerularia bombi confirmed that these fractions are yolk material (vitellogenin) taken up by ovaries. In parasitized queens oöcytes do not grow and the fractions are of a much lower concentration than in nonparasitized queens with maturing eggs. Therefore it appears that the parasite injures primarily the corpora allata known to stimulate the synthesis of yolk protein.