Phase polymorphism in Schistocerca gregaria: Assessment of juvenile hormone synthesis in relation to vitellogenesis

Juvenile hormone (JH) synthesis by the corpora allata of gregarious and solitarious phase females of Schistocerca gregaria was determined in vitro during the penultimate and last stadia as well as during the first gonotrophic period of adults. Generally, the corpora allata of solitarious females showed higher rates of JH synthetic activity. In addition, in adult females there was a temporal difference between the corpora allata activities of gregarious and solitarious locusts, the latter exhibiting relatively higher rates of JH synthesis early in the first gonotrophic period. The corpus allatum volumes of solitarious females were also generally larger than those of their gregarious counterparts; there was no synchrony between fluctuations in JH synthetic activity and changes in corpus allatum volume in either phase.The early onset of relatively high JH synthetic rates in solitarious females was correlated with the early detection, by rocket immunoelectrophoresis, of vitellogenin in the haemolymph and vitellin in the oöcytes. Vitellogenin appeared in the haemolymph on day 4 in solitarious females and on day 6 in gregarious females and vitellin appeared in the oöcytes on days 6 and 8 respectively. Oöcyte length at which vitellogenesis was first detected was 1.8 mm for gregarious and 1.3 mm for solitarious females. However, despite the accelerated onset of both vitellogenin synthesis and uptake, oöcyte maturation time of solitarious females was longer. In both gregarious and solitarious females, vitellogenin titres increased until oöcytes reached a length of about 4 mm and declined thereafter. Vitellin content of ovaries increased proportionately to oöcyte growth until they attained a length of 5.0 mm. The subsequent increase in length of oöcytes to maturity is attributed to postvitellogenic growth, possibly by hydration.     

The effects of starvation and subsequent feeding on juvenile hormone synthesis and oöcyte growth in Schistocerca americana gregaria

The effect of starvation on the synthesis of C₁₆ juvenile hormone (JH) and the growth of terminal oöcytes was assessed in Schistocerca americana gregaria at two times during adult life: before activation of the corpora allata and during the first gonotrophic cycle. In both groups, starvation resulted in a decline in JH synthesis within 2–3 days and rates of synthesis remained low throughout the experimental period. The growth rate of oöcytes which were not vitellogenic at the time of starvation was depressed whereas the percentage of resorption of vitellogenic oöcytes increased dramatically with starvation. Although the percentage of resorption increased in animals with vitellogenic oöcytes, some mature oöcytes were produced, particularly in animals in which the oöcytes were greater than 5 mm in length at the time of starvation. This suggests that oöcyte maturation can be divided into two distinct phases—an early phase of vitellogenesis associated with high rates of JH synthesis and a late phase, in oöcytes greater than 5 mm, associated with much lower rates of JH synthesis.Stimulation of JH synthesis by farnesenic acid in 5-day starved animals resulted in high rates of JH synthesis, indicating that starvation did not appreciably alter the enzymic activities of the final two stages in JH synthesis. Thus rate limitation did not occur at these stages.Feeding of 5-day starved animals resulted in a transient increase in the rate of JH synthesis. However, rates of JH synthesis and oöcyte growth remained subnormal throughout the observation period, suggesting that the effects of starvation cannot be entirely reversed by feeding. Thus starvation may decrease the reproductive potential of the females.     

Factors responsible for the initiation of a second oöcyte maturation cycle in the ovoviviparous cockroach Nauphoeta cinerea

The factors responsible for the initiation of a second oöcyte maturation cycle were investigated by measuring oöcyte growth, vitellogenin titre, and corpus allatum activity after injection of juvenile hormone and/or removal of the egg-case from pregnant females and by performing ovary and corpus allatum transplant experiments.Egg-case removal in late pregnancy results in immediate oöcyte growth, whereas in early pregnancy oöcyte growth is resumed only after a lapse of time, even after injection of juvenile hormone. This, however, induces an immediate increase in the haemolymph vitellogenin titre. A single injection of 2 or 10 μg of juvenile hormone II first stimulates some oöcyte growth after this lapse of time and later activates the corpora allata, which in turn leads to completion of oöcyte maturation. A repeat injection of 10 μg stimulates continuous oöcyte growth without activating the corpora allata. In the presence of an egg case, activation of the corpora allata is suppressed, even after injection of 2 μg of juvenile hormone III, and the oöcytes do not grow. Injection of higher doses stimulates oöcyte growth and leads to expulsion of the egg case in up to 95% of the females. This, however, is not a direct consequence of the increase in size of the ovaries. Ovary transplant experiment show that in young pregnant females the second generation of oöcyte is not yet competent for growth and that ovaries which are competent can mature in young pregnant females, treated with juvenile hormone, whose egg case has been removed.The results are summarized in a model demonstrating the various factors involved in regulating corpus allatum activity in oöcyte maturation and pregnancy and after application of juvenile hormone. We prepose that the corpus allatum activating effect of exogenous juvenile hormone is mediated by the growing oöcyte and that this activation can be suppressed by the continuous presence of exogenous juvenile hormone.     

Gonadotrophic effect of juvenile hormone in Blattella germanica: A rapid,simple quantitative bioassay

The German cockroach is convenient for assaying gonadotrophic effects of juvenile hormone (JH) analogues. The animals can be raised synchronously from egg to adult state in 2·5 months at 30°C, a shorter time than for any of the common laboratory-reared cockroaches. Last instar larvae can be stored for up to a month at 16 to 18°C and brought to 30°C to metamorphose when needed, providing a convenient source of bioassay animals. The assay takes 2 days to complete, less time than previously published gonadotrophic assays. The growth of terminal oöcytes of the ovary responds linearly with log dose between 0·08 and 0·8 μg of Cecropia JH-I. The analogues JH-I ethyl ester and methyl-juvenate have dose response curves parallel to that for JH-I, enabling potencies, r, relative to JH-I to be calculated (r = 1·01, 0·35 respectively). There is no significant effect of the volume of hormone vehicle between 2 and 8 μl. A 30 per cent increase in the precision of the bioassay is obtained by correcting the oöcyte growth for the fed-weight of the animal. The bioassay is adequate to resolve a twofold difference in potency using as few as 36 animals per analogue.     

Ovarian maturation in Leucophaea maderae: Juvenile hormone regulation of thymidine uptake into follicle cell DNA

Our research demonstrates that juvenile hormone (JH I) stimulates thymidine incorporation into ovarian follicle cell DNA in the ovoviviparous cockroach, Leucophaea maderae.A rapid, quantitative method for monitoring ³H-thymidine incorporation into ovarian DNA, in vitro, is described. Cultured ovarian tissue from L. maderae incorporates ³H-thymidine into DNA at a linear rate between 16 and 120 min; analysis of the incorporated label revealed at least 98% of it to be in DNA.Using L. maderae females that had been mated 7 days after adult emergence, we monitored the following biochemical phenomena during the 18–22 day period of terminal oöcyte growth: (1) ³H-thymidine incorporation into ovarian DNA: (2) general protein synthesis in fat body; and (3) specific fat body vitellogenin synthesis.Decapitation of mated females with maturing oöcytes arrested both ovarian DNA synthesis and fat body vitellogenin synthesis. Substantial restoration of both types of synthesis was induced by injection of JH I. The resumption of thymidine incorporation into DNA was localized in the follicular epithelium of the terminal oöcyte.In decapitated virgin females, injection of JH I stimulated oöcyte growth and ³H-thymidine incorporation into ovarian DNA. Dose and time response curves indicate that peak stimulation of ovarian DNA synthesis occurred between 72 and 96 hr after administration of a single optimal dose of 25 μg JH I. The concurrent manifestation of ³H-thymidine uptake into ovarian DNA and activity within the fat body indicates that a similar hormonal mode of action may be operative with respect to both tissue types in virgin females.     

Enhancement of juvenile hormone biosynthesis in locusts following electrostimulation of cerebral neurosecretory cells

Electrostimulation of the medial neurosecretory cells of day-1 adult female Locusta migratoria resulted in a significant enhancement of juvenile hormone biosynthesis by the corpora allata within 2–3 days of the operation, as determined by a radiochemical assay for juvenile hormone biosynthesis. This elevation in the rate of juvenile hormone biosynthesis was also reflected in basal oöcyte length, with the oöcytes of stimulated animals significantly larger than the sham-operated animals. Radio-frequency cautery of the cerebral axonal tracts of the medial neurosecretory cells prevented this enhancement in juvenile hormone biosynthesis and in basal oöcyte growth in both stimulated and sham-operated animals.Stimulation of the lateral neurosecretory cells resulted in a slight elevation in rates of juvenile hormone biosynthesis 2 days after the operation. However, after cautery of the medial cell tracts, a significant elevation in juvenile hormone biosynthesis was observed 1 and 2 days after stimulation. Basal oöcyte length in stimulated animals differed significantly from sham-operated animals only on day 6. Cautery of the medial cell tracts again attenuated oöcyte growth. Our results suggest that the medial neurosecretory cells are the source of an allatotropin that can be released by electrostimulation. This substance appears to operate directly on the corpus allatum, causing a change in the juvenile hormone biosynthetic machinery.     

Effects of electrocoagulation of cerebral neurosecretory cells and implantation of corpora allata on oöcyte development in Locusta migratoria

The implantation of active corpora allata into intact Locusta females during growth accelerates pre-vitellogenic oöcyte growth and vitellogenesis. Localised stimulation of yolk deposition follows the implantation of active corpora allata between the ovarioles demonstrating a gonadotrophic rôle for the corpus allatum hormone. Electrocoagulation of the median neurosecretory cells of the brain prevents vitellogenesis whilst pre-vitellogenic oöcyte growth occurs normally. Implantation of active corpora allata into females with ablated cerebral neurosecretory cells promotes vitellogenesis in a proportion of test animals although mature oöcytes are never produced.It is suggested that the rôle of the median neurosecretory cells during egg development in Locusta is primarily concerned with the activation and maintenance of activity of the corpora allata. The corpus allatum hormone acts both metabolically and gonadotrophically.     

Changes in follicle cell morphology,ovarian protein synthesis and ovarian DNA synthesis during oöcyte maturation in Leucophaea maderae: Role of juvenile hormone

Changes in follicle cell morphology were correlated with changes in rates of protein synthesis and DNA synthesis by the ovary during ovarian maturation in Leucophaea maderae. During the vitellogenic period of oöcyte development, which lasts approx, 15 days, morphological changes in the follicle cells are accompanied by moderate rates of ovarian protein synthesis and rapid rates of ovarian DNA synthesis. At approx. 15 days after mating, the shape of the follicle cells changes from cuboidal to squamous, ovarian DNA synthesis is arrested, and ovarian protein synthesis increases slightly. During the final period of oöcyte development, which lasts approx, two days, the interfollicular channels between the follicle cells have disappeared and the squamous follicle cells, which contain an extensive rough endoplasmic reticulum, deposit a chorion around the mature oöcyte. These morphological changes are accompanied by a radical increase in ovarian protein synthesis, while ovarian DNA synthesis remains arrested. Immediately before ovulation, ovarian protein synthesis starts to decline, reaching a minimal level 24 hr post-ovulation.Ovarian maturation is dependent on the presence of juvenile hormone (JH) only during the vitellogenic stage of oöcyte development. Decapitation of insects at any point during the first 10 days after mating arrests the synthesis of DNA and retards the synthesis of protein by the ovary, resulting in degeneration of the oöcyte. Subsequent injection of JH restores both events to normal levels within 72 hr. Decapitation on or after the tenth day following mating does not alter normal oöcyte development, chorion deposition, ovulation or egg case formation.Primary induction of protein synthesis in ovaries from virgin females can be achieved by either an in vivo or in vitro exposure of the tissue to JH, thus confirming a site of action for JH to be ovarian tissue. Electrophoretic analysis of the soluble proteins from JH-exposed ovaries in vivo reveals that JH stimulates general protein synthesis, rather than the synthesis of a specific major protein such as vitellogenin.     

Juvenile hormone regulation of structural changes and DNA synthesis in the follicular epithelium of Leucophaea maderae

Juvenile hormone (JH I) stimulates specific morphological and biochemical changes in the follicular epithelium surrounding the terminal oöcytes in Leucophaea maderae. These include extracellular and intracellular structural changes, increased rates of follicle cell DNA synthesis, and elevated follicle cell DNA concentrations.Using females decapitated 24 hr after ecdysis, we have shown that JH I injections stimulate the following structural changes in the follicular epithelium: the appearance of channels between adjacent follicle cells and of spaces between the follicular epithelium and the maturing oöcyte; an increase in follicle cell size; the development of an extensive rough endoplasmic reticulum system; and an enlarged nucleus within each follicle cell. No increase in the number of follicle cells surrounding the developing terminal follicles is found in 7-day JH I-treated females, although the terminal follicles are almost twice as long as those in untreated females.In addition, we have demonstrated that JH stimulates the following biochemical events in the ovary: a 3.5 fold increase in thymidine incorporation into follicle cell DNA, with no subsequent transfer of such DNA to the developing oöcyte, and a 1.4 fold increase in ovarian DNA in 7-day JH-treated females. These data indicated that JH stimulates follicle cell DNA synthesis. The absence of any corresponding division of follicle cells suggests that JH I may induce polyploidy in follicle cells.Extended exposure of decapitated females to JH I does not result in complete ovarian maturation. Although fat bodies in the treated insects continue to display an increasing rate of vitellogenin synthesis, DNA synthesis in the terminal follicles declines rapidly after day 9, and the terminal follicles ultimately degenerate.     

Study of oöcyte growth within the ovariole in a stick-insect, Clitumnus extradentatus

Growth of the sub-terminal follicle is hindered by the terminal oöcyte itself during maturation until its ovulation. An inhibition identical to that exercised by the sub-terminal oöcyte exists at the level of the third follicle. The inhibitory substance passes from one oöcyte to the next through the interfollicular tissue. Sub-terminal oöcytes have no particular action on the terminal follicles.Vitellogenesis requires stimulation from the tissues proximal to the ovariole. Both the oviduct and the interfollicular tissue could play a role in this stimulation. Chorionation is seen to be an autonomous mechanism.     

Uptake of vitellogenin into developing oöcytes of Locusta migratoria

The selective incorporation of vitellogenin into developing locust oöcytes was studied using ¹²⁵I-vitellin. Vitellogenin incorporation does not start before the oöcytes are 1.5 mm in length. It increases rapidly up to a maximum at 4.7 mm oöcyte length and decreases steadily until the eggs are fully developed (6.5 mm). Concentrations of serum proteins and vitellogenin in the haemolymph show parallel changes, vitellogenin titre reaching a maximum of 7.5 mg/ml. Incorporation rates for vitellogenin increase from 1.5 μg/hr/oöcyte (2.2 mm) up to 13.8 μg/hr/oöcyte (4.7 mm). In this range incorporation per unit surface area increases 4-fold. While the vitelline and chorionic membranes are being formed, the incorporation rates as well as the protein concentrations in the haemolymph decrease steadily until the second gonotrophic cycle starts. The hormonal basis for oögenesis and the mechanism for selective uptake of locust vitellogenin are discussed.     

Corpus allatum activity during overlapping cycles of oöcyte growth in adult female Melanoplus sanguinipes

Cycles of oögenesis in Melanoplus sanguinipes overlap to the extent that there are always 2 and occasionally 3 sets of vitellogenic oöcytes in the ovarioles at any one time. Three phases of vitellogenic oöcyte development can be distinguished: (1) An initial 24-hour phase of slow development (1.0–1.2 mm, 0.05–0.10 mm³). (2) A phase of rapid oöcyte growth (1.2–3.5 mm, 0.1–1.3 mm³). The duration of this phase is 2 days in the first cycle and 3 days in subsequent cycles. (3) A final phase of rapid oöcyte growth and maturation (3.5–4.5 mm, 1.3–2.8 mm³). Including the time taken for oviposition the duration of this latter phase is 3 days. Phases 1, 2 and 3 of cycles n + 2, n + 1 and n, respectively, overlap entirely. Activity of the corpora allata was measured using a radio-biosynthetic technique. A period of increased corpus allatum activity coincides with the initial part of phase 2 in each cycle. Each set of oöcytes is, thus, subject to 2 and occasionally 3 peaks of corpus allatum activity during development. Using these data a model of the control of oöcyte development has been devised     

Biosynthesis and titre of juvenile hormone during the first gonotrophic cycle in isolated and crowded Locusta migratoria females

Basal oöcyte length, corpus allatum volume and “in vitro” juvenile hormone biosynthesis were measured in isolated and crowded Locusta migratoria females at selected times during the first gonotrophic cycle. Using gas chromatography-mass spectrometry with selected ion monitoring, the juvenile hormone titre in the haemolymph of isolated and crowded females was also determined 1 and 4 days after fledging. The rate of oöcyte growth was more rapid in isolated females and a significant (P < 0.01) difference in mean length was apparent as early as 3 days after fledging. This early manifestation of a difference in rate of oöcyte growth was correlated with a difference in haemolymph juvenile hormone titre between isolated and crowded females. Whilst there was no difference in titre 1 day after fledging, by day 4 the juvenile hormone titre in isolated females was found to be approximately twice that in crowded females. There was no significant difference in the rates of juvenile hormone biosynthesis by corpora allata from isolated and crowded females on days 0 through to 6 after fledging. On day 8, however, the rates of juvenile hormone biosynthesis of corpora allata from isolated females were very high (mean value = 136 pmol/h/pair) and were significantly (P < 0.002) greater than those of corpora allata from crowded females. Day 8 was also the point in the first gonotrophic cycle at which the difference in the mean basal oöcyte length in isolated and crowded females was at a maximum. The mean volume of corpora allata from isolated females was greater than that of corpora allata from crowded females at all points at which measurements were taken during the first gonotrophic cycle.     

Initiation and regulation of oöcyte growth by the brain and corpora allata of the cockroach,Nauphoeta cinerea

Oöcytes of Nauphoeta cinerea begin to grow about 2 days after adult ecdysis. This growth can be totally prevented by surgical ablation of the corpora allata (CA) before day 2 and restored in a dose-related manner by injection of juvenile hormone (JH). Ovarian maturation can also be prevented in some animals by brain extirpation within a day of adult ecdysis but proceeds normally in others, indicating that the brain acts to promote oöcyte lengthening very soon after emergence. Wounding (mouthparts removal) blocks ovarian maturation in a similar percentage of animals, indicating that the ‘wounding effect’ is mediated by the brain. However, those wounded animals which do develop oöcytes do not reach normal values by autopsy on day 7, suggesting a temporary inhibition of the CA. Because the effects of head ligation, which effectively removes the brain as well as the CA, can be reversed by only a little more JH than the effects of allatectomy, we conclude that the primary rôle of the brain is to control the CA. We suggest that both stimulatory neurohumoral material and inhibitory nervous transmission may be utilized for this control.     

Haemolymph vitellogenin,juvenile hormone,and oöcyte growth in the adult cockroach Nauphoeta cinerea during first pre-oviposition period

In the cockroach Nauphoeta cinerea the incorporation of a protein of low solubility into the oöcytes begins at day 5 of its adult life. An immunologically identical protein appears in the haemolymph two days earlier. The concentration of this protein, i.e. ‘vitellogenin’ in the haemolymph increases up to the onset of yolk incorporation into the oöcytes. During ovarian development no correlation could be detected between vitellogenin titre and several other parameters (ovary dry weight, length of the basal oöcytes, haemolymph protein concentration, body weight and age when ovulation occurred). In young females vitellogenin titre depends on the age, i.e. the volume of the corpora allata and hence on the presence and the titre of JH. During the period of egg maturation the total haemolymph protein concentration generally tends to drop while materials not precipitable by trichloracetic acid circulate at higher concentration after ecdysis and before ovulation.Early decapitation prevents vitellogenin synthesis and oöcyte growth, but when JH is applied to decapitated females, the normal vitellogenin titre is re-established, ovarian development, however, cannot be fully resumed. A dose-response curve shows that serial application of the hormone is much more effective than single large doses. Farnesylmethylester, a JH mimic, is about a hundred times less active, but more persistent than JH. Copulation seems to enhance the synthesis and release of endogenous JH, while food and water uptake are necessary to guarantee and optimal ovarian development. JH and high vitellogenin titre never restore ovarian development in females deprived of food and/or water or in those decapitated shortly after ecdysis.     

Effects of precocene I and II on flight behaviour in Oncopeltus fasciatus, the migratory milkweed bug

Treatment of newly emerged adult Oncopeltus fasciatus with the corpus allatum inhibitors. 7-methoxy-2,2-dimethyl chromene or 6,7-dimethoxy-2,2-dimethyl chromene (preocene I and II) results in an inhibition of long-term flight (presumed migratory) behaviour in both males and females and inhibition of oögenesis in females. Treatment of reproductive females with precocene briefly stimulates flight behaviour (which ceases in such females as oviposition begins) and then subsequently inhibits it. Oviposition also ceases in such females and oöcyte resorption occurs. Topical application or injections of JH III to precocenetreated animals results in immediate restoration of the tendency to make long tethered flights while corpora cardiaca extract injections, corpora cardiaca implantation, sham implantation, sham injections and sham topical applications were ineffective in restoring prolonged flight behaviour to precocene-treated animals.Restoration of flight by JH III injection was observed within 1 hr after treatment with the hormone. These results indicate that JH is necessary for prolonged flight and presumably migratory behaviour in this species and its stimulatory effect on flight behaviour is immediate. Possible mechanisms of action of the hormone on flight behaviour are discussed.     

Food quality and quantity in relation to egg production in Locusta migratoria migratorioides

Oöcyte development is not initiated when female Locusta migratoria migratorioides are fed on poor, low-protein Agropyron repens. Survival on this diet is improved by the provision of water and small quantities of lush A. repens. When maturing female locusts (with developing oöcytes), previously fed on lush grass, are provided with the poor-quality grass the rate of egg pod production is reduced and terminal oöcyte resorption is increased. The final percentage resorption and the possibility of oviposition is determined by the total quality of food during vitellogenesis. In poor-grass fed locusts the levels of ingestion and utilization are low and suggest that quantitative factors are likely to be critical.Quantitative studies show that the provision of gradually decreasing amounts of A. repens produces corresponding decreases in the rate of egg pod production and increases in terminal oöcyte resorption. When the quantity of food ingested is reduced, the rate of oöcyte development is first reduced, followed at lower levels of feeding by an increase in terminal oöcyte resorption. Ingestion of less than 80 mg (dry weight) of grass/female per day is insufficient to initiate oöcyte development in locusts whose somatic growth period is normal. The significance of these results is discussed.     

Cellular and volumetric changes in relation to the activity cycle in the corpora allata of Diploptera punctata

In the corpora allata (CA) of the viviparous cockroach, Diploptera punctata, a cycle of juvenile hormone (JH) synthesis during ovarian maturation can be correlated with cyclical changes in CA volumes and cell numbers. Uptake of [³H]-thymidine occurs in nuclei of CA cells during periods of increase in cell number. Both members of a pair of CA maintain symmetry of volume, cell number and rate of JH synthesis. After a cycle of CA activity, the CA can be transplanted to a young, allatectomized female, where they support a second wave of oöcyte development.     

On the relative importance of juvenile hormone and vitellogenin for oöcyte growth in the cockroach Nauphoeta cinerea

The corpora allata of castrated females of Nauphoeta grow only very slightly and do not reach a volume greater than that of the glands of normal females during gestation. These small corpora allata are, however, active and are responsible for the synthesis of vitellogenin (female specific protein) in large amounts. Besides vitellogenin the other haemolymph proteins are also synthesized and accumulated in the haemolymph in much higher concentrations than in normal females. Implanted oöcytes grow in castrated as well as in normal females at about the same rate until the tenth day of the oöcyte maturation period. Thereafter they only grow in castrated females. If castrated and normal females are decapitated, their protein content decreases. At the same time the growth stimulating capacity of their haemolymph decreases at a much faster rate. If oöcytes are implanted in castrated and decapitated females after 4 days they cannot grow any more although the vitellogenin titre of the haemolymph is still much higher than it is at any time in normal females. It can be concluded that vitellogenin alone cannot induce oöcyte growth and that juvenile hormone is necessary as well for vitellogenin synthesis as for its incorporation into the oöcytes. However, in insects rich in vitellogenin juvenile hormone leads to a more rapid oöcyte growth than in insects containing only small amounts of this protein.     

Influence of a juvenile hormone analogue on vitellogenin synthesis and oögenesis in larvae of Nauphoeta cinerea

In experiments on the synthesis of the vitellogenic protein, farnesylmethylester, a juvenile hormone (JH) analogue, was injected into female Nauphoeta cinerea larvae at various stages during their development. Two and 4 days after injection, 2 μl of haemolymph were assayed in a vitellogenin immunodiffusion test. In second last and last instar larvae less than 6 days before adult ecdysis, high doses (100 μg) of farnesylmethylester are necessary to induce vitellogenin synthesis, whereas older last stage larvae and decapitated adults respond to small doses (1 μg) with the synthesis of vitellogenin. It seems that the competence to synthesize the vitellogenic protein changes at the time of induction of the moulting process. If farnesylmethylester is injected into last instar larvae with a supposedly high titre of ecdysone, the vitellogenic protein can be detected in the haemolymph of a small percentage of animals only.Oöcyte maturation can be observed in last instar larvae injected after the fifth to ninth day with farnesylmethylester. The observed volume changes of the corpora allata suggest that an absence of JH for a short time is necessary for the oöcytes to become competent to grow. Last instar larvae treated with farnesylmethylester become larval-adult intermediates with partly developed oöcytes, demonstrating a simultaneous juvenilizing and gonadotropic influence of the JH analogue. In last instar larvae injected with farnesylmethylester a partial degeneration of already maturing oöcytes is induced at the time when the ecdysone titre is supposedly high and the possible reasons for this are discussed.