Histological and cytological studies on the ovary of Nauphoeta cinerea (Blattaria,Oxyhaloidea) during the first reproductive cycle

Histological studies were performed on the ovary of the ovoviviparous cockroach Nauphoeta cinerea during the first reproductive cycle by means of optical microscopy and histoautoradiography, and electron microscopy. The oöcyte chamber is composed of follicle cells, the oöcyte and a layer of symbiotic bacteria at the level of the microvillous border of the oöcyte. The first reproductive cycle begins with a short inactive period preceding the appearance of vitellogenin. During this period, the follicular epithelium achieves its development by a mitotic flare. From the 3rd day on, vitellogenin is synthesized by the fat body and large intercellular spaces appear between the follicular cells, in conjunction with a rapid growth of the oöcyte, which takes up selectively the vitellogenin by means of pinocytotic vesicles. These coalesce to give the yolk globules. Along with these phenomena, the proteosynthetic apparatus and its activity in the follicular cells increase slowly. After about the 12th day, the intercellular spaces disappear and the follicular epithelium which has now a very well developed proteosynthetic apparatus, begins to synthesize and lay down the egg membranes. After ovulation, the empty oöcyte chamber collapses and the follicular epithelium shows rapid degeneration processes (large cytolysosomes) that destroy the chamber completely during the gestation period. At the beginning of the 2nd cycle, there only remain a cell or two of the previous follicular epithelium and a very large annular piece of basement membrane.     

Isolation and sequence of a partial vitellogenin cDNA from the cockroach,Blattella germanica (L.) (Dictyoptera,Blattellidae), and characterization of the vitellogenin gene expression

A partial cDNA clone of the vitellogenin gene from the cockroach Blattella germanica has been isolated from a cDNA expression library using an anti-vitellin–vitellogenin antiserum probe. The analysis of cDNA inserts gave a sequence of 2,645 nucleotides corresponding to the 3′ region. The deduced amino acid sequence is 825 residues long and is similar to the homologous portion of the vitellogenin of other insect species, especially that of the mosquito Aedes aegypti. RNA hybridization studies indicated that the vitellogenin gene expression is limited to the fat body of adult females. The pattern of expression during the first vitellogenic cycle was approximately parallel to that of vitellogenin production by the fat body previously described. The availability of a cDNA probe for the B. germanica vitellogenin gene represents a useful tool to study the molecular action of hormones affecting vitellogenin synthesis in this species. Arch. Insect Biochem. Physiol. 38:137–146, 1998. © 1998 Wiley-Liss, Inc.     

Vitellogenin fluctuations in haemolymph and fat body and dynamics of uptake into oöcytes during the reproductive cycle of Diploptera punctata

Haemolymph and fat body soluble protein titres have been examined during the reproductive cycle of Diploptera punctata, with particular emphasis on the occurrence of vitellogenin and its uptake into the developing oöcytes. Vitellogenin was first detected in the haemolymph of mated females 2 days after adult eclosion at about the same time that vitellin deposition in basal oöcytes began. Peak haemolymph titres of vitellogenin occurred on day 6, correlated with the completion of yolk uptake. Thereafter vitellogenin levels declined and were generally undetectable throughout most of gestation, rising again shortly before parturition in association with the second gonotrophic cycle. Total haemolymph protein levels were not correlated with vitellogenesis.Soluble fat body vitellogenin titres of mated females remained low during the first oöcyte growth period but then rose several-fold at its completion and remained high throughout pregnancy and the second gonotrophic cycle. Total fat body soluble proteins decline after adult eclosion in association with oöcyte growth.Vitellin accumulation in basal oöcytes was related linearly to increase in volume until the onset of chorion formation. Thus no post-vitellogenic growth period was detected.     

Onset of vitellogenin production and vitellogenesis,and their relationship to changes in the midgut epithelium and oocytes in the tickDermacentor variabilis

InDermacentor variabilis (Say), the onset of vitellogenin production and vitellogenesis (up-take of vitellogenin into oocytes) began during the rapid-engorgement feeding period. Mating was required for both vitellogenin production and vitellogenesis to complete the tick's life cycle. Complete immunological identity, as measured by Ouchterlony's double diffusion test, existed between vitellogenin from the fat body, midgut and hemolymph, and vitellin from the ovaries and eggs. Antivitellin antibody did not react with host hemoglobin nor with fat body, midgut, and ovary extracts from feeding females prior to rapid engorgement, feeding unmated females, or unfed or fed males. Some unmated females fed for 13 days and then hand-detached from the host eventually began oviposition after going through a preoviposition period. In these ticks, organ extracts from the midgut, fat body and ovary reacted with antivitellin antibody. The presence or absence of presumed vitellogenic cells in the midgut and yolk bodies in oocytes corresponded with the presence or absence of vitellogenin and vitellogenesis as measured by Ouchterlony's test. Presumed vitellogenic cells increased in size during the preoviposition period. These cells reached their greatest size during the time when the most eggs were being produced, and then declined in size toward the end of oviposition. Vitellogenin was deposited directly into developing yolk bodies in oocytes and was not processed through lysosomes. Feeding was the process that initiated the formation of eggshell cuticle. Detachment from the host was required for the initiation of oviposition.     

Juvenile hormone-controlled vitellogenin synthesis in Locusta migratoria fat body. Hormonal induction in vivo.

Biosynthetic processes related to the production of vitellogenin (yolk precursor protein) have been examined in the fat body of adult female Locusta migratoria. Vitellogenin-producing capacity was assayed by incubation of fat body with [³H]leucine, followed by precipitation from the medium with specific antiserum. In normal development, vitellogenin synthesis began at about Day 7 after emergence and became maximal at about Day 13, when this protein accounted for 60% of the total fat body protein output. The production of other proteins increased to a lesser extent, becoming maximal at about Day 6. The incorporation of uridine into fat body RNA rose to a maximum at Day 8, which coincided with a marked increase in tissue RNA content. The DNA content in adult female fat body approximately doubled between Days 3 and 8. Vitellogenin synthesis, and the increases in RNA and DNA, were prevented by removal of the corpora allata (the source of juvenile hormone). In allatectomized locusts, vitellogenin synthesis was induced by JH or an analog, ZR-515. Applied topically in acetone, these gave steep dose-response curves, half-maximal at 75 and 150 μg, respectively. After a single treatment with ZR-515, fat body vitellogenin production rose slowly during 48 hr, then steeply to a maximum at 72 hr, but after decay of this effect during 10 days, a second application of ZR-515 induced renewed synthesis with little initial lag. Hormone treatment produced a smaller increase in the output of other proteins, and an increase in incorporation into RNA which preceded the major rise in vitellogenin synthesis. Male fat body produced little or no vitellogenin. These results are consistent with action of JH at the gene level.     

Patterns of haemolymph vitellogenin and ovarian vitellin in the German cockroach, and the role of Juvenile Hormone

Abstract. The concentrations of fat body and haemolymph vitellogenin and ovarian vitellin during the first gonadotropic cycle of the cockroach Blattella germanica (L.) (Dictyoptera, Blattellidae) have been studied. For these purposes, a polyclonal antibody against B. germanica vitellogenin and vitellin has been obtained, and an ELISA to quantify these proteins has been developed. Ovarian vitellin levels follow a pattern which parallels those of basal oocyte growth and Juvenile Hormone production by the corpora allata. This suggests that Juvenile Hormone regulates vitellogenin uptake into oocytes. Fat body and haemolymph vitellogenin levels give cyclic and parallel patterns. However, the cycle of Juvenile Hormone appears delayed with respect to that of vitellogenin. We suggest that the production of Juvenile Hormone, although cyclic in profile, does not modulate alone the cycle of vitellogenin. At least a supplementary mechanism, apparently independent of Juvenile Hormone, may be involved in the decline of vitellogenin production at the end of the vitellogenic cycle.     

Expression and activity of 3-hydroxy-3-methylglutaryl-CoA synthase and reductase in the fat body of ovariectomized and allatectomized Blattella germanica

Abstract. . 3-Hydroxy-3-methylglutaryl-CoA (HMG-CoA) synthase and HMG-CoA reductase show coordinated regulation in the fat body of Blattella germanica females. Since the profile of activity is parallel to the cycle of vitellogenin production, we postulated a link between the mevalonate pathway and vitellogenesis. Here we have studied both enzymes in females of B.germanica modified by ovariectomy (which leads to a saturable accumulation of vitellogenin) and allatectomy (which supresses vitellogenesis). Protein levels and enzymatic activity for both enzymes in ovariectomized specimens rose early in the first days of imaginal life and remained high until the end of the period studied, whereas controls showed cyclic profiles. In allatectomized specimens the same parameters were measured on day 4 of adult life and values were much lower with respect to controls. The parallelism between the patterns of HMG-CoA synthase and reductase, and that of vitellogenin, suggests a functional relationship between the mevalonate pathway and the glycosylation of vitellogenin through dolichol intermediates.     

Juvenile hormone-controlled vitellogenin synthesis in Locusta migratoria fat body: Cytological development

Cytological development in the fat body of adult female Locusta migratoria, related to vitellogenin synthesis, has been studied by light and electron microscopy. In the newly-emerged adult, the cells are filled with lipid droplets, which indent the nucleus, and with fields of glycogen, while ribosomes and endoplasmic reticulum are scarce. Correlated with the onset of vitellogenin synthesis, about day 8 of adult life, the nucleus enlarges, lipid droplets and glycogen decrease, and rough endoplasmic reticulum and Golgi complexes become the most abundant organelles. These changes reflect a conversion of the principal role of the fat body from nutrient storage to the synthesis and secretion of protein. They are prevented by allatectomy, and restored by subsequent treatment with the juvenile hormone analogue, ZR-515. Late in the first gonotrophic cycle, about day 20, dense bodies, vesicle-containing bodies and lysosomes are seen, indicating recycling of cellular materials. Five days after ZR-515 treatment, when protein synthesis has declined, the rough endoplasmic reticulum appears in arrays adjacent to lipid droplets, possibly awaiting reactivation. By the use of ferritin-labelled antivitellin immunoglobulin, vitellogenin has been localized intracellularly in the RER saccules and Golgi vesicles, and extracellularly in channels between the folded plasma membranes, showing sites of accumulation and secretion of this protein.     

Origin and formation of the royal fat body of the higher termite queens

The formation of the royal fat body was studied by electron microscopy in three species of higher termites (Macrotermes bellicosus, Macrotermes subhyalinus, and Cubitermes fungifaber). The swarming alate imago has a storage fat body typical of most insects. In non-physogastric young queens, during the fasting period, the adipocytes deplete their reserves and then, along with the increased vitellogenesis, acquire protein-synthesizing structures (R.E.R.). During the development of physogastry they progressively specialize in protein synthesis and secretion and undergo many cell divisions. The cytological change is paralleled by a spatial reorganization of the fat body. Observations on the transformation of imaginal adipocytes into royal adipocytes show that the royal fat body is derived from the imaginal fat body and not from the tracheal cells as previously claimed.     

Absence of female-specific protein in the hemolymph of stable fly Stomoxys calcitrans (L.) (Diptera: Muscidae)

Changes, during the reproductive cycle, in fat body, hemolymph, and ovarian proteins of the stable fly Stomoxys calcitrans were characterized quantitatively and qualitatively using sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE). Protein content of all three tissues increased after blood feeding. Fat body protein increased first, followed by hemolymph and ovarian proteins. SDS-PAGE failed to identify vitellogenin in both female hemolymph and fat body samples. No single protein or group of proteins predominated at any stage of the reproductive cycle. Comparisons between male and female stable fly hemolymph and fat body proteins failed to detect female-specific proteins. Female-specific proteins, however, were detected in the hemolymph of four other species of Diptera.     

Termite queens have disproportionately more DNA in their fat body cells: reproductive division of labor and endoreduplication

Increases in DNA content caused by endoreduplication are widely observed in the metabolically active tissues of plants and animals. During egg production, insect females synthesize very large amounts of vitellogenin in their fat bodies, and female fat bodies of some insects become polyploid to accelerate vitellogenin production. Social insects have developed reproductive division of labor, wherein queens lay most of the eggs while other individuals have reduced fertility and undertake tasks required for maintaining the colony. Therefore, only queens are engaged in vitellogenin synthesis for egg production in social insects. Here, we show that termite queens have disproportionately more DNA in their fat body cells. Our DNA content analysis using flow cytometry demonstrated that more cells contained 4C‐DNA than 2C‐DNA in the fat bodies of Reticulitermes speratus queens. This high level of endoreduplication was not found in the fat body cells of other castes. This caste‐dependent doubling of DNA content in fat body cells suggests that termites exploit endoreduplication to boost egg production, in conjunction with the development of reproductive division of labor. This study highlights nuclear polyploidization as an adaptive strategy in social insects.     

Phospholipid synthesis in the fat body endoplasmic reticulum during primary and secondary juvenile hormone stimulation of vitellogenesis inLeucophaea maderae

Summary Juvenile hormone (JH) treatment coordinately stimulated the dose-dependent synthesis of vitellogenin and endoplasmic reticulum (ER) membrane phospholipids in fat body cells from allatectomized adult females ofLeucophaea maderae. Animals were pulse-labeled in vivo with [³²P] to simultaneously measure the rates of synthesis of the phosphorylated subunits of vitellogenin and the structural phospholipids of the ER membranes. Phospholipid synthesis in ER membranes from nontarget tissues for JH such as thoracic muscle, midgut, and larval fat body was unresponsive to hormone treatment. The proliferation of ER in response to JH treatment was thus restricted to tissue that was competent to synthesize vitellogenin.Primary and secondary vitellogenin induction was measured in allatectomized adult females treated 12 days apart with JH-III. The time-course of the primary response for vitellogenin and ER phospholipid synthesis was characterized by a 24 h latent period, a rapid increase to a maximum at 72 h, and then a gradual decline. During secondary induction, vitellogenin accumulated in the hemolymph nearly twice as fast as before and peaked at a concentration of 38 g/l. This vitellogenin titer was approximately two-fold higher than that found at the height of the primary response. During both primary and secondary stimulation with JH, ER phospholipid synthesis, as measured by [¹⁴C]choline incorporation into microsomal phosphatidylcholine, was stimulated five-fold over the untreated control animals. The amplified production of vitellogenin during the secondary response was associated with a 24 h-earlier peak of ER phospholipid synthesis in the fat body.     

Ultrastructural immunocytochemical localization of vitellogenin in the fat body of the blowfly,Calliphora vicina Rob.-Desv. (erythrocephala Meig.) by use of the unlabeled antibody-enzyme method

Summary The unlabeled antibody-enzyme method was used to demonstrate ultrastructurally the specific localization of vitellogenin in the fat body of Calliphora. In control flies the binding sites to vitellogenin were localized in secretory granules situated in the Golgi complex, and in larger bodies named composite secretory granules. These composite granules appear to be formed when a part of a Golgi complex containing secretory granules and a number of small vesicles become surrounded by a common membrane. Ovariectomized flies, which apparently do not produce secretory granules, exhibited no immunocytochemical staining. Ovariectomized flies in which the administration of ecdysterone induced formation of secretory granules, also revealed specific staining on these granules. This is the first ultrastructural evidence of: (a) the specific localization of vitellogenin in secretory granules of the fat body of an insect; (b) the relationship between the presence of the ovary, and of ecdysterone, and the synthesis of vitellogenin by the fat body.     

Temporal variation of vitellogenin synthesis in Ectatomma tuberculatum (Formicidae: Ectatomminae) workers

Workers of the ant species Ectatomma tuberculatum (Ectatomminae) have active ovaries and lay eggs that are eaten by the queen and larvae (trophic eggs). Vitellogenins are the main proteins found in the eggs of insects and are a source of nutrients. The aim of this study was to characterize the period of vitellogenin production in workers of E. tuberculatum. The vitellogenin was identified from queen and worker eggs by SDS-PAGE. Anti-vitellogenin antibodies were obtained and used to detect this protein in the fat body and haemolymph of workers at different ages. Vitellogenin from E. tuberculatum consists of two polypeptides of 31 and 156 kDa. In the eggs of queens, the 156 kDa polypeptide is cleaved into two subunits of 36 and 123 kDa. The analysis of the haemolymph of workers showed that the secretion of vitellogenin varies with age. The secretion is initiated around the fifth day after emergence, with peak production from days 20 to 60, and stops around day 100. The variation in production is related to the different activities performed by the workers within the colony, suggesting that vitellogenin may have an important role in maintaining age polyethism.     

Fat body is the site of vitellogenin synthesis in the soft tick,Ornithodoros moubata

Summary Vitellogenin (Vg) synthesis in cultured tissues was analysed biochemically in a soft tick,Ornithodoros moubata. Nine tissue fractions dissected from reproductive females were incubated in vitro in a specially designed Ringer containing³⁵S-methionine. The synthesis of total protein and Vg was assayed by the radioactivity incorporated into precipitates with trichloroacetic acid and antivitellin (Vn)-serum, respectively. Fat body was the most active tissue in Vg synthesis, which comprised 46% of the Vg synthesis by all tissues and 42% of total protein synthesis by fat body. Protein synthesized by the fat body and precipitated with anti-Vn-serum was shown by electrophoresis and fluorography, to consist of six radioactive polypeptides corresponding to the components of Vg. Vg synthesized in cultured fat body was first accumulated in the tissue and secreted into the medium during incubation. Some tissues other than fat body showed low Vg synthesis (in each, less than 12% of total protein synthesis) which, however, may be due to contamination by fat body cells as seen with the scanning electron microscope (SEM). SEM also showed that fat body cells in the active stage of Vg synthesis expanded about 10-fold in length. Immunohistochemical analysis showed a very strong reaction with anti-Vn-IgG in the cytoplasm of fat body from reproductive females. Fat body from unfed females and other tissues including midgut, did not show any specific fluorescence. A positive reaction was obtained with developing oocytes. These results indicate that the fat body is the only site of Vg synthesis in this tick.Abbreviations Vg vitellogenin - Vn vitellin - SDS sodium dodecyl sulfate - PAGE polyacrylamide gel electrophoresis - SEM scanning electron microscopy - TCA trichloroacetic acid     

Effect of actinomycin-D on the fat body RNA content in Dysdercus koenigii (Heteroptera: Pyrrhocoridae)

The effect of actinomycin-D on the RNA content of the total fat body was studied on day 3, 4, 5 and 6 of the first reproductive cycle in the females. Actinomycin-D exhibited its highest inhibitory effect in insects injected on day 4 and a lower degree of the effect was seen in insects injected on day 5. These results suggest that by the end of day 4, a major quantity of DNA-dependent RNA, necessary for vitellogenin synthesis, has already been synthesised and accumulated.     

Rhipicephalus sanguinius: localization of vitellogenin synthesis by immunological methods and electron microscopy

In ovipositing Rhipicephalus sanguinius (Latrelle), complete immunological identity existed between vitellogenin from the midgut, fat body, and hemolymph and vitellin from eggs. This supported the hypothesis that the same vitellogenin was synthesized by both the midgut and fat body, then released into the hemolymph and transported to the ovary. Vitellogenin was taken up unaltered by the oocytes during vitellogenesis to become vitellin. Antivitellogenin did not react with host (dog) hemoglobin. Transmission electron microscopy showed specialized cells with large amounts of rough endoplasmic reticulum, Golgi complexes, and secretory granules in the midgut and fat body of ovipositing females that were absent in the midgut and fat body of fed males. It is suggested that these cells synthesize vitellogenin.