A role for ecdysteroids in the phase polymorphism of the desert locust

Abstract. Locusts show density-dependent continuous phase polymorphism; they appear in two forms or phases, gregarious and solitary, and there is a continuous range of intermediates between the extreme phases. Although earlier studies showed that there are no major phase-dependent differences in the titres of ecdysteroid in the haemolymph of desert locusts, Schistocerca gregaria , recent studies showed some minor differences in the timing of the main peak of ecdysteroids. In crowded penultimate- and last-instar hoppers, peak titres were lower but longer-lasting, whereas in isolated hoppers they were higher but of shorter duration. The major component of the haemolymph peak of ecdysteroid was 20-hydroxyecdysone in both isolated and crowded hoppers, but differences were found in the relative amounts of two minor components (makisterone A-like compound and highly polar products). In S. gregaria adults, the regression of the prothoracic glands was irregular and subject to high individual variations, but phase-dependent differences in the rate of regression were significant, and the adult glands did not produce physiologically significant amounts of ecdysteroids. Peak titres of ecdysteroid in the haemolymph were higher in isolated than in crowded adults. Similar to larvae, adults of the solitary phase contain more ecdysone in the haemolymph than those of the gregarious phase. Moreover, the phase characteristic titres of ecdysteroid in the adult stage can be shifted from one phase to another phase in response to appropriate changes in density. In contrast, the maximum amount of ecdysteroids in both ovaries and eggs was significantly higher in the gregarious than in the solitary phase. The amounts, and to some extent the types of ecdysteroids, were the only difference between ovaries and eggs from solitary and gregarious locusts. In addition, in newly hatched larvae, the amount of ecdysteroid was more than five times higher in gregarious than in solitary phase.     

Distribution and metabolism of exogenous ecdysteroids in the egyptian cotton leafworm Spodoptera littoralis (lepidoptera: noctuidae)

After ingestion of various amounts of either [³H]ecdysone or [³H]20-hydroxyecdysone (0.8 ng to 10 μg) by sixth instar larvae of the Egyptian cotton leafworm Spodoptera littoralis, apolar metabolites are rapidly detected in the gut and frass. Hydrolysis of the apolar products with Helix hydrolases releases solely [³H]ecdysone or [³H]20-hydroxyecdysone, respectively. This, coupled with the formation of chemical derivatives (acetonide and acetate) which cochromatograph with authentic reference compounds on hptlc and hplc demonstrates that these apolar metabolites consist of ecdysone or 20-hydroxyecdysone esterified at C-22 with common long-chain fatty acids. The major fatty acids have been identified by RP-hplc and their contribution to the mixture determined. In contrast, [³H]ecdysone injected into the haemolymph of S. littoralis is metabolized to yield 20-hydroxyecdysone, ecdysonoic acid, and 20-hydroxyecdysonoic acid. Thus, two different pathways exist for the metabolism of ecdysteroids in this species. In addition to an essentially polar pathway operating on injected and endogenous ecdysteroids, exogenous ecdysteroids entering the gut of S. littoralis are detoxified, yielding apolar ecdysteroid 22-fatty acyl esters which are rapidly excreted. The significance of these results in relation to the effects of ingested ecdysteroids on S. littoralis is discussed. Arch. Insect Biochem. Physiol. 34:329–346, 1997. © 1997 Wiley-Liss, Inc.     

Ecdysone metabolism in the host-parasitoid-system Trichoplusia ni/Chelonus sp

In unparasitized 4th and 5th-instar larvae of Trichoplusia ni and in 4th-instar larvae parasitized by Chelonus sp. 20-hydroxyecdysone, 20,26-dihydroxyec-dysone, and 20-hydroxyecdysonoic acid were the predominant metabolites formed 2 h after injection of [³H]ecdysone. Other unidentified metabolites were seen, but none seemed to be specific for either parasitized or unparasitized larvae. The major difference between parasitized and unparasitized larvae was seen with respect to the quantity of apolar (unidentified) and polar metabolites (20-hydroxyecdysonoic acid and unidentified ones), which were produced to a greater extent in parasitized larvae. Ecdysone was rapidly converted into 20-hydroxyecdysone and the other polar metabolites in all stages investigated, and the parasitoid seemed not to affect the conversion of ecdysone into 20-hydroxyecdysone. When analyzing the fate of [³H]ecdysone in host and parasite separately, at a stage when the parasite drinks hemolymph of its host, we observed that 10–20% of the radioactivity was recovered from the parasitoid. Analysis of the parasitoid's ecdysteroids revealed that ecdysone and 20-hydroxyecdysone represented only a small proportion of the recovered labeled ecdysteroids, the majority being apolar and polar metabolites. Our data suggest that the parasitoid takes up ecdysteroids from its host, converts them, and to some extent releases apolar metabolites into the host.     

Humoral stimulation of the larval and adult prothoracic glands in Schistocerca gregaria

Fluctuations in ecdysteroid production by explanted prothoracic glands (PG) during the penultimate and last larval instars parallel changes in ecdysteroid titer in the hemolymph. The in vitro output of ecdysteroids increases up to 30-fold when PG are co-cultured with the brain. Maximal amounts of ecdysteroids are produced when both PG and brain are taken from larvae at the time of the molt-inducing ecdysteroid peaks (days 2–3 in the penultimate and days 5–6 in the last instar), and also from day 3 last instar larvae that exhibit a small rise of hemolymph ecdysteroids. Detailed investigations on penultimate instar larvae revealed that their PG become sensitive to the stimulation on day 1 (about 24 h after ecdysis), but the stimulatory brain potential is restricted to days 2 and 3. Both the stimulatory capacity of the brain and the sensitivity of PG are lost on days 4 and 5, i.e., after the ecdysteroid surge on day 3. PG explanted from young adults do not secrete appreciable amounts of ecdysteroids but can be stimulated to ecdysteroid production with active larval brains. Arch. Insect Biochem. Physiol. 36:85–93, 1997. © 1997 Wiley-Liss, Inc.     

Metabolism of [3H]-ecdysone in Schistocerca gregaria; formation of ecdysteroid acids together with free and phosphorylated ecdysteroid acetates

The metabolism of [³H]-ecdysone has been investigated at times of low and high endogenous ecdysteroid tit re, in early and late fifth-instar Schistocerca gregaria larvae, respectively. Ecdysone-3-acetate, 20-hydroxyecdysone, and 20,26-dihydroxyecdysone were identified as metabolites in both the free form and as polar conjugates. Comparison of the intact polar conjugates of the ecdysteroid acetates on two HPLC systems with the corresponding authentic compounds indicated that they were 3-acetylecdysone-2-phosphate and 3-acetyl-20-hydroxyecdysone-2-phosphate. Other major polar metabolites were identified as ecdysonoic acid and 20-hydroxyecdysonoic acid. Ecdysone metabolism in fifth-instar S. gregaria is apparently an age-dependent process. Early in the instar, excretion of both free and conjugated ecdysteroids, as well as ecdysteroid 26-acids, occurs. At this stage the level of ecdysteroid acetates in the conjugated (phosphate) form is high, in contrast to the free ecdysteroids, where ecdysone predominates. When the endogenous hormone titre is high, the formation of ecdysteroid acetates is less, the major excreted matabolites at that stage being conjugated 20-hydroxyecdysone together with ecdysteroid-26-acids, but little free ecdysteroids. Acetylation of ecdysone occurs primarily in the gastric caecae. Ecdysone-3-acetate (mainly as polar conjugate) is also a major product of ingested ecdysone in early fifth-instar Locusta migratoria.     

Comparative studies on ecdysone metabolism between mature larvae and pharate pupae in the fleshfly,Sarcophaga peregrina

Metabolites of radioactive ecdysone or 20-hydroxyecdysone in larvae and pharate pupae of Sarcophaga peregrina were separated and identified by using thin-layer chromatography, high-performance liquid chromatography, and chemical methods. At the larval stage ecdysone was metabolized to biologically less active ecdysteroids predominantly through 20-hydroxyecydsone, at the pharate pupal stage, to other ecdysteroids which were tentatively identified as 26-hydroxyecdysone, 3-epi-26-hydroxyecdysone, and 3-epi-20,26-dihydroxyecdysone. Ecdysteroid acids were found in the polar metabolites during pharate pupal-pupal transformation, but scarcely detected in the larval metabolites. These acids were presumed to be ecdysonoic acid, 20-hydroxyecdysonoic acid, and their epimers. The conjugates of ecdysteroid that released the free ecdysteroids by enzymatic hydrolysis were produced more in larvae than in pupae, whereas the very polar ecdysteroids that were not affected by the enzyme were found more in pupae. Therefore, there are different metabolic pathways of ecdysone between these two successive developmental stages, and the alteration of the metabolic pathway may serve as one of the important factors in a regulatory mechanism of molting hormone activity which is responsible for normal development of this insect.     

Regulation of cytochrome P-450 dependent steroid hydroxylase activity in Manduca sexta: effects of the ecdysone agonist RH 5849 on ecdysone 20-monooxygenase activity

The non-steroidal ecdysone agonist RH 5849 (1,2-dibenzoyl-1-tert-butylhydrazine) was found to inhibit in a dose-response and apparently competitive fashion the cytochrome P-450 dependent ecdysone 20-monooxygenase activity in the midgut of wandering stage last instar larvae of the tobacco hornworn, Manduca sexta. More effectively on a per molar basis than the naturally occurring molting hormones ecdysone and 20-hydroxyecdysone, RH 5849 was also found to elicit the dramatic 50-fold increase in midgut steroid hydroxylase activity (which normally occurs with the onset of the wandering stage) when injected into competent head or thoracic ligated pre-wandering last instar larvae. These data support and extend the potential usefulness of RH 5849 as a pharmacological probe for further investigating the actions of ecdysteroids and their role(s) in the regulation of ecdysteroid monooxygenases.     

Characterization of acetyl-CoA: Ecdysone 3-acetyltransferase in Schistocerca gregaria larvae

Characterization of the acetyltransferase (acetyl-CoA: ecdysone 3-acetyltransferase) which catalyzes the conversion of ecdysone into ecdysone 3-acetate was carried out in gastric caecae of day 7 last instar larvae of Schistocerca gregaria. This enzyme is one of the enzymic systems involved in the inactivation of ecdysteroids. The acetyltransferase exhibited a microsomal subcellular localization, an apparent K_m for ecdysone of 71 μM, a maximal specific activity of 7.2 nmol/min/mg of protein and was inhibited competitively in the presence of 20-hydroxyecdysone with K_i = 68.8 μM. The enzyme required acetyl-CoA as co-substrate for its activity, the apparent K_m for acetyl-CoA being 47.2 μM. Acetic acid could not replace acetyl-CoA as the co-substrate, indicating that the enzyme is an acetyl-CoA: ecdysone acetyltransferase and not a hydrolase. Similarly, esterification of ecdysone was not observed when long-chain fatty acyl-CoA derivatives were substituted as co-substrates. The reaction was linear for 20 min and with protein concentration up to 0.8 mg/ml.The formation of 20-hydroxyecdysone 3-acetate has been demonstrated in the same microsomal fraction and required also acetyl-CoA as co-substrate. The apparent K_m of the acetyltransferase for 20-hydroxyecdysone was 53.5 μM, revealing that the enzyme had a somewhat stronger affinity for 20-hydroxyecdysone than for ecdysone.     

Correlations between juvenile hormone esterase activity,ecdysone titre and cellular reprogramming in Galleria mellonella

Juvenile hormone esterase (JHE) activity, ecdysone titre, and developmental competence of the epidermis were determined in last instar larvae and pupae of Galleria mellonella. Haemolymph JHE activity reaches a peak before increases are observed in ecdysone titre both during larval-pupal and pupal-adult metamorphosis. JHE activity is low during the penultimate larval instar although general esterase activity is relatively high. In last instar larvae two ecdysone peaks are noted after the increase in JHE activity. Furthermore, epidermal cell reprogramming occurs just after the increase in haemolymph JHE activity and possibly before the first increase in ecdysone titre. This was tested by injection of high doses of β-ecdysone into last instar larvae of different ages resulting in rapid cuticle deposition. Reprogramming occurred if the resulting cuticle was of the pupal type. These correlative observations may increase our understanding of the relative importance of an ecdysone surge in the absence of JH in reprogramming of the insect epidermis.     

The identification and titres of conjugated and free ecdysteroids in developing ovaries and newly-laid eggs of Schistocerca gregaria

Ecdysteroid levels throughout ovarian development and in newly-laid eggs of S. gregaria have been determined. A simple method for the separation of free and conjugated ecdysteroids is described. Both free and polar conjugated ecdysteroids are present at the end of oögenesis and in newly-laid eggs, but the polar conjugated ecdysteroids always predominate; 95% of the total ecdysteroid in newly-laid eggs is in the conjugated form. Ecdysone, 2-deoxyecdysone and 20-hydroxyecdysone have been fully characterized from both the ‘free’ and ‘conjugated’ fractions. The presence of traces of 26-hydroxyecdysone in the ‘conjugate’ fraction was indicated by HPLC analyses. The levels of ecdysteroid released from the conjugates of newly-laid eggs were 35 μg/egg pod (44 μg/g wet weight) for ecdysone, 16 μg/egg pod (19.4 μg/g) for 2-deoxyecdysone and 5 μg/egg pod (6.1 μg/g) for 20-hydroxyecdysone. The level of free ecdysone found in newly-laid eggs was 2 μg/egg pod (2.6 μg/g).     

Activity of the prothoracic gland and its sensitivity to prothoracicotropic hormone in the penultimate and last-larval instar of Bombyx mori

The time course of secretion of ecdysone in vitro by the prothoracic glands of Bombyx mori was studied through the penultimate and last-larval instars. Ecdysone was produced by the glands in high amounts by the penultimate instar at 72 and 84 h while the glands in the last instar exhibited a high activity over 4 days around the time of gut purge and thereafter. The glands in the penultimate instar produced ecdysone at a low level throughout the instar before the sharp peak of activity, when they became inactive and remained so for the first 3 days of the last instar after when they regained secretory activity. Sensitivity of the glands to prothoracicotropic hormone varied in accord with the changes in their secretory activity. Inactive glands were not stimulated by 22K-prothoracicotropic hormone. In addition, glands with maximal activity in the penultimate instar were insensitive to 22K-prothoracicotropic hormone. These results suggest that the prothoracic glands in the penultimate and last-instar larvae are physiologically different.     

Metabolism of ecdysteroids by a chitin-synthesizing insect cell line

A chitin-synthesizing cockroach cell line (UMBGE-4) previously shown to secrete ecdysteroids was analyzed for its ability to metabolize potential precursors of ecdysone (e.g., 2-deoxyecdysone, 2,22-dideoxyecdysone, 2,22,25-trideoxyecdysone, and cholesterol). All, except cholesterol, were actively metabolized by UMBGE-4 cells. However, all but 2-deoxyecdysone were converted to polar and hydrolyzable metabolites, and not to ecdysone. Labeling with cholesterol was unsuccessful. Labeling experiments with molting hormones, i.e., ecdysone and 20-hydroxyecdysone, confirmed that this cell line can metabolize ecdysteroids and allowed identification of some of the products. Molting hormones were converted into acetate conjugates and polar conjugates which were often double-conjugates, i.e., polar conjugates of acetate conjugates. Labeling experiments with ecdysone demonstrated that this cell line possesses a low ecdysone 20-hydroxylase activity. The capacity of UMBGE-2 cells, which do not synthesize chitin or ecdysteroids, was also examined. Neither ecdysone nor 20-hydroxyecdysone was significantly metabolized by UMBGE-2 cells. 2-Deoxyecdysone and 2,22-dideoxyecdysone were very slowly metabolized respectively to more polar compounds.     

Qualitative and quantitative analyses of juvenile hormone and ecdysteroids from the egg to the pupal molt in Trichoplusia ni

A method was developed to determine in the same extract juvenile hormone and various types of ecdysteroids in precisely staged eggs and larvae of Trichoplusia ni. Ecdysteroids were tentatively identified on the basis of their retention time in ion suppression reversed-phase HPLC and their cross-reactivity with two relatively non-specific, complimentary antibodies, whereas juvenile hormone was identified using reversed-phase HPLC combined with Galleria bioassay. Freshly laid eggs contained low levels of immunoreactive ecdysteroids. Mid-polar ecdysteroids increased in the phase of segmentation (14-18 h) and 1st larval cuticle formation (36-44 h), when 20-hydroxyecdysone and 20,26-dihydroxyecdysone were found to be predominant. Only traces of ecdysone and 26-hydroxyecdysone were seen. Toward hatching ecdysteroids decreased and represented mainly compounds more polar than 20,26-dihydroxyecdysone. In larval development ecdysteroids were low at the beginning of the feeding phases, increased toward cessation of feeding, and reached highest levels 12-15 h before ecdysis. In feeding stages ecdysone and 20-hydroxyecdysone were predominant, whereas in molting stages they were seen together with 20,26-dihydroxyecdysone and 20-hydroxyecdysonoic acid. The juvenile hormone titer was very low in freshly laid eggs and was high (approximately 25 ng/g) in embryos at the stage of 1st larval cuticle formation and eye pigmentation. In eggs we tentatively identified juvenile hormones I and II, whereas in larval stages juvenile hormone II appeared to be the predominant or exclusive juvenile hormone. Its titer fluctuated rapidly and was high in early 1st-instar larvae and again before the molts into the 3rd, 4th, and 5th instar. Highest titers were reached concomitant with the peak in 20-hydroxyecdysone 12-15 h before ecdysis.     

Ecdysone metabolism and distribution during the pupal-adult development of Manduca sexta

The metabolism and distribution of endogenous ecdysone and injected [³H]ecdysone were studied during the pupal-adult development of Manduca sexta. Well-characterized antisera were used to detect and quantify endogenous metabolites by radioimmunoassay (RIA) following their separation by ion-suppressed reverse phase, and normal phase, high performance liquid chromatography. Identical chromatographic procedures were employed to determine the metabolic fate of the [³H]ecdysone in the haemolymph pool. These studies revealed the sequential appearance in the haemolymph and gut of progressively oxidized metabolites of ecdysone—hydroxylation at C-20 was followed by hydroxylation at C-26. The data are suggestive of both the induction of the steroid hydroxylases (oxidases) by substrate or other effector substances and the possible coordination of developmental events by ecdysteroids other than 20-hydroxyecdysone.In the haemolymph, two highly-polar conjugates of ecdysone were observed together with conjugates of the other free ecdysteroids, especially those hydroxylated at C-26. In contrast, relatively little 20-hydroxycdysone conjugate was detected in the insect. As adult development proceeded, both endogenous and radiolabelled ecdysteroids were increasingly localized in the gut, so that just prior to eclosion most ecdysteroids were present in the meconium of the high gut (rectal pouch). The peak titres and the kinetics of appearance of ecdysone, 20-hydroxyecdysone, and 20,26-dihydroxyecdysone were similar for both haemolymph and gut (and for males and females), but considerably higher levels of C-26 oxidized (acid) metabolites of ecdysone and 20-hydroxyecdysone were localized in the gut. Although levels of highly-polar ecdysteroid conjugates found in the haemolymph and gut were similar, considerable amounts of three less polar ecdysone conjugates, of 3-α-epimers of ecdysone and 20-hydroxyecdysone, and of a substance tentatively identified as 2-deoxyecdysone were found only in the gut. Whether ionized, conjugated, or free, the gut ecdysteroids did not appear to equilibrate with the haemolymph compartment.Differences were observed in the metabolism kinetics of exogenously administered radiolabelled ecdysone when compared to the endogenous ecdysteroids; and some RIA positive gut metabolites did not become significantly radiolabelled. This suggests that injection of ecdysone may not simulate the endogenous secretion of ecdysone or its subsequent metabolism and distribution completely accurately.     

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.     

Identification of the molting hormone of the sweet potato (Bemisia tabaci) and greenhouse (Trialeurodes vaporariorum) whitefly

In order to identify the whitefly molting hormone, whole body extracts of mature 4th instar and newly formed pharate adult Bemisia tabaci (Biotype B) and Trialeurodes vaporariorum were prepared and subjected to reverse phase high performance liquid chromatography (RPHPLC). Ecdysteroid content of fractions was determined by enzymeimmunoassay (EIA). The only detectable ecdysteroids that were present in significant amounts in whitefly extracts were ecdysone and 20-hydroxyecdysone. The concentrations of 20-hydroxyecdysone in B. tabaci and T. vaporariorum extracts, respectively, were 40 and 15 times greater than the concentrations of ecdysone. The identity of the two ecdysteroids was confirmed by normal phase high performance liquid chromatography (NPHPLC). When ecdysteroid content of RPHPLC fractions was assayed by radioimmunoassay (RIA), small amounts of polar ecdysteroids were also detected indicating that these ecdysteroids have a very low affinity for the antiserum used in the EIA. Ecdysteroid at 10.4 mM administered by feeding stimulated 2nd instar whitefly nymphs to molt. Based on our results, it appears that 20-hydroxyecdysone is the whitefly molting hormone.     

Endocrine interrelationship between the parasitoid Chelonus sp. and its host Trichoplusia ni

The egg-larval parasitoid Chelonus sp. induces the precocious onset of metamorphosis in the 4th (penultimate) stadium of its host Trichoplusia ni, emerges from the prepupa, and then feeds on it. Qualitative and quantitative changes in ecdysteroids and juvenile hormone were measured. Hemolymph of 3rd-to 4th-instar host larvae and the parasitoids they contained, as well as nonparasitized and parasitized eggs, were analyzed. In the host hemolymph a broad peak of ecdysteroids during molting into the 4th stadium and a continuous increase from day 2 (onset of precocious wandering) until day 4 (emergence of parasitoid) were observed; 20-hydroxyecdysone and 20,26-dihydroxyecdysone were predominant. The juvenile hormone titer fluctuated in the 3rd and early 4th stadium and fell to undetectable levels shortly before the precocious onset of wandering. The parasitoid's ecdysteroids started to increase on the molt to the 2nd instar (= early 4th instar of the host) and thereafter fluctuated on a high level, 20-hydroxyecdysone, 20,26-dihydroxy-ecdysone, and ecdysone being predominant. The juvenile hormone titer was high in late 1st-instar parasitoids, decreased to low levels at ecdysis into the 2nd instar, and increased again to high levels in the 2nd-instar larvae at the time when their shape changed from flat to cylindrical. After ecdysis to the 3rd instar the juvenile hormone titer fell. A comparison revealed that both ecdysteroids and juvenile hormone fluctuate independently in parasitoid and host at most stages, suggesting that the parasitoid produces its own hormones. The first data on ecdysteroids and juvenile hormones in the egg stage of a parasitoid/host system are reported. At the stage of eye pigmentation parasitized eggs contained more immunoreactive midpolar ecdysteroids than non-parasitized ones. 20-Hydroxyecdysone and 20,26-dihydroxyecdysone were the predominant ecdysteroids in both nonparasitized and parasitized eggs, but the latter contained several additional ecdysteroids which were not seen in nonparasitized eggs. The titer of juvenile hormone was similar in both. Shortly before hatching the ecdysteroids were low in parasitized and nonparasitized eggs, but the content of juvenile hormone was much higher in the former. At this stage the majority of parasitoids have already eclosed and teratocytes are released. The results of HPLC analysis indicated the presence of juvenile hormone III together with juvenile hormones I and II in parasitized eggs, but only juvenile hormones I and II in nonparasitized eggs.     

Juvenile hormones and their titer regulation in Galleria mellonella

Juvenile hormones I, II and III occur in Galleria but JH II is dominant. Its concentration reaches a peak of 3 pmol/g body wt in the penultimate instar, drops to zero in the last larval instar and, except for a small peak in prepupae (0.2 pmol/g), remains undetectable until pharate adults. After emergence the titer reaches over 5 pmol/g in both sexes. Presence of JH II is associated with JH II acid; JH III acid occurs even more often, including stages lacking JH III. Brain implantation into freshly ecdysed last instar larvae effects a similar JH peak as in the penultimate instar and causes an extra larval molt. The opposite treatment, i.e. decerebration of fresh last instar larvae, elicits a continuous rise of JH II to 10 pmol/g and an increase of otherwise rare JH I to 3 pmol/g. Sham operations of these larvae or decerebration of old larvae elevate practically only JH II titer to 1–1.5 pmol/g. Implanted brain-corpora cardiaca-corpora allata complexes maintain in various hosts 0.14–1.6 pmol/g of JH II. The significance and regulation of these fluctuations in JH titer are discussed.     

Degradation of juvenile hormone and methylation of juvenile hormone acid by corpora cardiaca–corpora allata of the cockroach,Nauphoeta cinerea: II. Physiological aspects

In vitellogenic females of Nauphoeta cinerea, injected (10R)-juvenile hormone (JH) III was degraded more rapidly than racemic JH III: we measured a half-life of 21 min (with or without coinjection of lipophorin) for the former and 24 min (with coinjection of lipophorin) and 43 min (without coinjection of lipophorin) for the latter. One to two hours after injection, JH III acid was the major metabolite observed; in addition, several highly polar products were found. The half-life of injected racemic JH III acid was 19 min with coinjection of lipophorin and 4 min without. The JH III acid titer in hemolymph was low (around 5–10 pmol/ml) in last instar larvae and previtellogenic and pregnant females and reached higher values (40–100 pmol/ml) in vitellogenic and ovulating females. Racemic JH III acid could be methylated in vitro to JH III by corpora cardiaca–corpora allata (CC-CA) from penultimate instar larvae and females at stages between adult ecdysis and ovulation and at the very end of pregnancy, but not by CC-CA from last instar larvae and adult females at earlier stages of pregnancy. This indicates that CC-CA are capable of methylating JH III acid only at stages when JH III is detectable in the hemolymph. In double-labelling experiments with CC-CA from vitellogenic females and L-[¹⁴C]methionine and [³H]JH III acid as precursors, we observed that only a small proportion (1–8%) of total biosynthesized JH III was derived from JH III acid when the latter was present at physiological concentration. This suggests that in vivo recycling of JH III acid by CC-CA plays only a minor role in the regulation of the titer of JH III and JH III acid.