A putative new juvenile peptide hormone in lepidopteran insects.

A growth-blocking peptide (GBP) with repressive activity against juvenile hormone (JH) esterase has been isolated from the last (6th) instar larval plasma of the armyworm Pseudaletia separata (Lepidoptera: Noctuidae) parasitized by the parasitoid wasp Apanteles kariyai (Hymenoptera: Braconidae) (1,2). This study demonstrates that GBP not only exists in the plasma of parasitized last instar larvae, but also in the plasma of unparasitized penultimate (5th) instar larvae, while the plasma of last instar larvae does not contain any detectable amount of GBP. The detection of GBP in unparasitized penultimate instar larvae, before the final larval molt, demonstrates that this factor is naturally occurring in the insect larva before the last larval instar and is seemingly coordinating, along with JH, the regulation of juvenile characteristics. This finding suggests the existence of a new type of juvenile peptide hormone in lepidopteran insects.     

Hormonal control of invertebrate behavior

Invertebrates show a wide variety of behaviors that are influenced by hormones. In insects the involvement of hormones at a particular life stage is directly correlated with the complexity of the behavioral repertoire at that stage. In larval stages, the steroid hormone, ecdysone, when present with juvenile hormone, apparently causes the behaviors observed during the periodic molts. At the end of larval life, ecdysone in the absence of juvenile hormone triggers the onset of premetamorphic behaviors such as wandering behavior and cocoon-spinning behavior. In insects having complete metamorphosis, the emergence (eclosion) of the adult from the pupal case is accomplished by a stereotyped program of movements that are triggered by a peptide hormone. In moths, injection of this “eclosion hormone” into competent recipients will cause the release of the eclosion program. Also this program can be elicited by the hormone from the isolated abdominal central nervous system (CNS). The onset of reproductive behavior in females of various species requires juvenile hormone. In addition, certain peptides are then involved in the transition from virgin to mated behaviors. Also, pupatitive peptide factors trigger specific stereotyped behaviors such as those involved in mate attraction and in oviposition. In males, the control is simpler. Juvenile hormone is required for the maturation of sexual behavior in only a few species. But in at least one insect group, the cockroaches, a neurosecretory hormone serves to release directly copulatory behavior. Social behavior and migratory behavior in certain insects are also under hormonal influence. Hormones play a prominent role in regulating the behavior of gastropod mollusks. The best studied examples involve the hormonal stimulation of egg-laying behavior by CNS peptides. Also, peptide hormones cause stereotyped changes in specific identified neurons in the CNS of various gastropods. In at least some cases, these latter changes are related to arousal from aestivation.With their simple nervous systems, invertebrates are especially suited for studies on the mode of action of hormones on the nervous system. In most cases the behavioral effects of these hormones appear to be due to their direct action on the CNS. Indeed, the isolated moth CNS will respond to the eclosion hormone by generating the motor program that gives rise to the emergence behavior, and various isolated molluscan preparations will respond to hormones with stereotyped neural responses. By the direct application of hormone to the surface of identified nerve cells in mollusks it has been possible to localize target cells for specific hormones. Little is known of the mode of action of ecdysone or juvenile hormone in altering behavior. Peptide hormones appear to have effects which long outlast the actual presence of the hormone. In at least two cases, cyclic AMP has been implicated as a mediator of the hormonal response.     

Juvenile hormone esterase activity repressive factor in the plasma of parasitized insect larvae

A proteinaceous factor that represses plasma juvenile hormone esterase activity in parasitized insect larvae has been isolated and partially characterized from last instar larvae of the armyworm Pseudaletia separata parasitized with the wasp Apantales kariyai. Purification procedures consisted of extraction with 25% ethanol, gel filtration and reversed phase high performance liquid chromatography. Plasma juvenile hormone esterase activity in Day 3 last instar larvae was repressed by 50% when larvae were injected on Days 1 and 2 with 6.5 pmol of the purified peptide, which has a molecular weight of about 4,500 Da. The application of the factor also causes more than a 2-day delay in the onset of pupation. The sequence of 23 amino acid residues at the amino terminus of the factor was determined as follows: H-Glu-Asn-Phe-Ser-Gly-Gly-Xaa-Val-Ala-Gly-Tyr-Met- Arg-Thr-Pro-Asp-Gly-Arg-Xaa-Lys-Pro-Thr-Phe-Tyr-Gln-.     

Juvenile hormone III biosynthesis by the larval corpora allata of Manduca sexta

A radioimmunoassay (RIA) for juvenile hormone III has been established which quantifies the biosynthesis of this hormone in vitro by the corpora allata of larvae and pupae of the tobacco hornworm, Manduca sexta. The specificity of the RIA for homologues and metabolites of juvenile hormone III was determined and it was found that the antibody was specific for juvenile hormone III and its acid. The juvenile hormone III RIA activity synthesized in vitro by corpora allata from day-5 last-instar larvae was identified as juvenile hormone III by high pressure liquid chromatography. The kinetics of hormone synthesis by corpora allata from selected stages during larval-pupal development revealed differential rates of synthesis, suggesting that juvenile hormone III may have a hormonal function in the larva and that regulation of its synthesis may occur. The significance of these developmental fluctuations in rates of juvenile hormone III synthesis by the corpora allata is discussed in relation to the haemolymph titres of the hormone.     

Juvenile hormone regulates the expression of the gene encoding ceratotoxin a,an antibacterial peptide from the female reproductive accessory glands of the medfly Ceratitis capitata

Ceratotoxin A is an antibacterial peptide produced by the reproductive female accessory glands of the medfly Ceratitis capitata. To investigate whether ceratotoxin A gene expression was affected by juvenile hormone, which has gonadotropic functions in adult insects, newly emerged female medflies were treated with precocene II, an antiallotropin compound capable of inhibiting juvenile hormone biosynthesis. Daily treatment of newly emerged flies with precocene II blocked ceratotoxin A gene expression in a dose-dependent manner. Ceratotoxin A gene expression could be recovered after withdrawl of precocene II treatment. Moreover, the effect of precocene II on ceratotoxin A gene expression could be countered by simultaneous treatment with methoprene, a juvenile hormone analogue. The effects of precocene II and methoprene treatments on the growth of both ovaries and accessory glands was also investigated. Our data suggest that ceratotoxin A gene expression is modulated by juvenile hormone.     

Improved assay conditions for measurement of corpus allatum activity in vitro in the adult Colorado potato beetle, Leptinotarsa decemlineata

Assay conditions for the short-term, radiochemical, in vitro determination of the spontaneous rate of juvenile biosynthesis by isolated corpora allata from Leptinotarsa decemlineata have been further improved, permitting the measurement of juvenile hormone biosynthesis by individual pairs of corpora allata. The final incubation product has been identified as juvenile hormone III with the aid of High-performance liquid chromatography (HPLC) and juvenile hormone esterase degradation. Using the new assay conditions, the activities of adult corpora allata during maturation were found to be significantly higher in reproductive, long-day animals than in pre-diapause, short-day beetles. During diapause no activity was detectable, whereas corpora allata from post-diapause beetles were reactivated totally after 5 days. Simultaneous determination of the in vitro rates of juvenile hormone biosynthesis and corpus allatum volumes revealed no clear correlation although the results suggest that the volume may be indicative of the maximal capacity for juvenile hormone production. Corpora allata from a population of beetles did not display any synchronous diurnal rhythmicity.     

Seasonal changes in juvenile hormone titers and rates of biosynthesis in honey bees

Honey bee colonies can respond to changing environmental conditions by showing plasticity in age related division of labor, and these responses are associated with changes in juvenile hormone. The shift from nest taks to foraging has been especially well characterized; foraging is associated with high juvenile hormone titers and high rates of juvenile hormone biosynthesis, and can be induced prematurely in young bees by juvenile hormone treatment or by a shortage of foragers. However, very few studies have been conducted that study plasticity in division of labor under naturally occurring changes in the environment. To gain further insight into how the environment and juvenile hormone influence foraging behavior, we measured juvenile hormone titers and rates of biosynthesis in workers during times of the year when colony activity in temperate climates is reduced: late fall, winter, and early spring. Juvenile hormone titers and rates of biosynthesis decreased in foragers in the fall as foraging diminished and bees became less active. This demonstration of a natural drop in juvenile hormone confirms and extends previous findings when bees were experimentally induced to revert from foraging to within-hive tasks. In addition, endocrine changes in foragers in the fall are part of a larger seasonally related phenomenon in which juvenile hormone levels in younger, pre-foraging bees also decline in the fall and then increase the following spring as colony activity increases. The seasonal decline in juvenile hormone in foragers was mimicked in summer by placing a honey bee colony in a cold room for 8 days. This suggests that seasonal changes in juvenile hormone are not related to photoperiod changes, but rather to changes in temperature and/or colony social structure that in turn influence endocrine and behavioral development. We also found that active foragers in the late winter and early spring had lower juvenile hormone levels than active foragers in late spring. In light of recent findings of a possible link between juvenile hormone and neuroanatomical plasticity in the bee brain, these results suggest that bees can forage with low juvenile hormone, after previous exposure to some threshold level of juvenile hormone leads to changes in brain structure.     

Cholecystokinin mRNA in Atlantic herring, Clupea harengus--molecular cloning, characterization, and distribution in the digestive tract during the early life stages

The mRNA of the peptide hormone cholecystokinin (CCK) was isolated from juvenile Atlantic herring, Clupea harengus, by RT-PCR. The open reading frame encodes a 137 amino acid-long precursor protein. The peptide sequence of herring CCK-8, DYMGWMDF, is identical to that of higher vertebrates and elasmobranchs, and contains methionine in the sixth position from the C-terminus, which has not been reported previously in teleosts. Expression analysis by in situ hybridization shows that positive endocrine-like cells were mainly located in the pyloric caeca and to a less extent in the rectum of the juvenile. A few positive cells were also found in the pyloric portion of the stomach and the intestine. CCK cells were present in all the larvae examined from the day of hatching onwards. Although the CCK cells were scattered throughout the whole midgut, no signals were detected in either the foregut or the hindgut. Since herring larvae have a straight gut, the distribution pattern of CCK cells seems to be reflected in the anatomy of the gut.     

Amino acid sequence of a peptide with both molt-inhibiting and hyperglycemic activities in the lobster, Homarus americanus

A hydrophobic peptide of 71 residues was isolated from lobster sinus gland extracts that prolonged intermolt periods and lowered ecdysteroid titers in juvenile lobsters. Removal of the N-terminal pyroglutamyl residue allowed sequencing of 30 of the first 36 residues. Additional data were obtained from HPLC-purified fragments from endoproteinase cleavages (Lys-C, Glu-C, Arg-C, Asp-N), and carboxypeptidase Y digestion. This is the first reported amino acid sequence of a crustacean molt-inhibiting hormone. This peptide also has significant hyperglycemic activity.     

cDNA cloning of a mandibular organ inhibiting hormone from the spider crabLibinia emarginata

Mandibular organs (MO) produce a crustacean juvenile hormone, methyl farnesoate (MF). MO activity is negatively regulated by factors, called mandibular organ inhibiting hormones (MOIHs), from the crustacean sinus gland X-organ complex in the eyestalks. Three MOIHs have been isolated previously from the spider crabLibinia emarginata and are characterized as members of the crustacean hyperglycemic hormone (CHH) neuropeptide family. In the research reported here, a full length cDNA sequence of 972 bp of a MOIH was isolated by screening a cDNA library constructed from the eyestalks ofLibinia emarginata. This cDNA sequence encodes a preprohormone peptide with 137 amino acid residues, including a 26-amino acid long signal peptide, a 34-amino acid long precursor peptide, a dibasic peptide, the full length of 72-amino acid long MOIH, and a tri-peptide Gly-Lys-Lys which designates the potential amidation site at the C-terminus of the mature peptide.     

Critical roles for juvenile hormone and its esterase+ in the prepupa of Trichoplusia ni

In the caterpillar Trichoplusia ni (Lepidoptera: Noctuidae) it has been demonstrated by allatectomy that the appearance of juvenile hormone during the prepupal stage is crucial for the successful larval-pupal ecdysis of most larvae. Application of juvenile hormone or juvenile hormone esterase inhibitors at key times disrupted normal development as well. Thus the subsequent disappearance of juvenile hormone is regulated by degradation by juvenile hormone esterase in addition to a hypothetical reduction in biosynthesis. This reduction in juvenile hormone titer in the prepupa is just as critical for normal development as was its previous appearance. These observations on the critical role of juvenile hormone in the prepupa are in contrast to observations in some other species. For instance, in the case of Manduca sexta (Lepidoptera: Sphingidae), juvenile hormone is considered only supplementary to the action of prothoracicotropic hormone in the postwandering stage and primarily is required for normal pupal development. It thus appears that even within the Lepidoptera the role of juvenile hormone in prepupal development can vary dramatically.     

Juvenile hormone controls egg laying and fertility in Drosophila virilis during starvation

Degradation of juvenile hormone and reproductive function during starvation and experimental increase of the juvenile hormone titer were studied in wild type and mutant D. virilis females incapable to respond to heat stress by changes in juvenile hormone metabolism and fertility. After 24-hour starvation, the females of both lines were characterized by a decreased level of juvenile hormone degradation, 24-hour delay of egg laying, increased egg laying within 3 h after the termination of starvation, and decreased fertility within three days. Application of exogenous juvenile hormone also led to a decreased level of its degradation and 24-hour arrest of egg laying. Experimental increase of the juvenile hormone titer before the beginning of starvation led to a sharply increased fertility (number of laid eggs and number of progenies) within the first 24 h after the termination of starvation. The dynamics of juvenile hormone degradation and of fertility were similar after starvation and upon application of the exogenous hormone. The role of juvenile hormone in the control of egg maturation and laying under stress conditions has been discussed.     

Juvenile Hormone Controls Oviposition and Fertility in Drosophila virilis during Starvation

Degradation of juvenile hormone and reproductive function during starvation and experimental increase of the juvenile hormone titer were studied in wild type and mutant D. virilis females incapable to respond to heat stress by changes in juvenile hormone metabolism and fertility. After 24-hour starvation, the females of both lines were characterized by a decreased level of juvenile hormone degradation, 24-hour delay of oviposition, increased oviposition within 3 h after the termination of starvation, and decreased fertility within three days. Application of exogenous juvenile hormone also led to a decreased level of its degradation and 24-hour arrest of oviposition. Experimental increase of the juvenile hormone titer before the beginning of starvation led to a sharply increase fertility (number of laid eggs and number of progenies) within the first 24 h after the termination of starvation. The dynamics of juvenile hormone degradation and of fertility were similar after starvation and upon application of the exogenous hormone. The role of juvenile hormone in the control of egg maturation and laying under stress conditions has been discussed.     

Effects of juvenile hormone and precocene II on the metabolic rate of the digestive system, fat body and ovaries of the insect Oncopeltus fasciatus

The metabolic rate of midgut, fat body and ovaries from Oncopeltus fasciatus adult female has been studied, comparing the results with that from juvenile hormone or precocene II treated insects. Neither juvenile hormone nor precocene II had any effect on midgut and fat body. Precocene II treatment increased the oxygen consumption rate of ovaries, which in turn remained undeveloped. Juvenile hormone had no detectable effects on the metabolic rate of ovaries, other than accelerate their development.     

INSECT HORMONES IN DEVELOPMENT

Advances in studies of prothoracicotropic hormone (ecdysiotropin), ecdysteroids and juvenile hormones in the past decade are considered:
1. Until recently there has been little progress with prothoracicotropic hormone. The development of a sensitive bioassay for the hormone promises to produce rapid advances.
2. Current methods of hormone analysis are described, with detection limits. The application of these methods in studies of hormones at different stages and in different tissues of insects have revealed a far greater complexity in hormone titres than was predicted from classical studies.
3. Very few studies employ chemical characterization of hormones and some assays do not distinguish biologically inactive metabolites of the hormones from the active hormones. Many studies have thus failed to reveal the numerous rapid fluctuations in hormone titre necessary for insect development.
4. While ecdysteroids act, via a receptor, on specific chromosome sites, the cellular mode of action of juvenile hormone in larval development is still unknown. Recent evidence suggests that juvenile hormone acts prior to the time at which its effects are realized by ecdysteroids.
5. Insect hormones produce dramatic changes in gene activity and their co-ordinate control of specific protein synthesis has been the basis for a number of 'model systems' of gene control in higher eukaryotes.     

The effects of allatectomy and juvenile hormone replacement on the development of host-seeking behaviour and lactic acid receptor sensitivity in the mosquito Aedes aegypti

Host-seeking behaviour in newly emerged Aedes aegypti (L.) females is not expressed immediately after adult eclosion but develops gradually over a period of approximately 3-4 days. This development is accompanied by an apparent maturation of the antennal chemosensory afferent neurons involved in the detection of the airborne host attractant lactic acid. Since these events coincide in time with juvenile hormone-dependent previtellogenic ovarian growth and since the expression of other reproduction-associated behaviour has previously been shown to be dependent on juvenile hormone, the effects of juvenile hormone removal and replacement on the development of host-seeking behaviour and the response characteristics of the lactic acid-sensitive receptors were investigated. No effect of juvenile hormone removal by allatectomy or juvenile hormone replacement or augmentation by topical application of the juvenile hormone mimic methoprene was found. It was concluded that this hormone is not involved in the appearance of host-seeking behaviour or the apparent maturation of the lactic acid receptors that occurs during early imaginal life.     

A perspective for understanding the modes of juvenile hormone action as a lipid signaling system

The juvenile hormones of insects regulate an unusually large diversity of processes during postembryonic development and adult reproduction. It is a long-standing puzzle in insect developmental biology and physiology how one hormone can have such diverse effects. The search for molecular mechanisms of juvenile hormone action has been guided by classical models for hormone-receptor interaction. Yet, despite substantial effort, the search for a juvenile hormone receptor has been frustrating and has yielded limited results. We note here that a number of lipid-soluble signaling molecules in vertebrates, invertebrates and plants show curious similarities to the properties of juvenile hormones of insects. Until now, these signaling molecules have been thought of as uniquely evolved mechanisms that perform specialized regulatory functions in the taxon where they were discovered. We show that this array of lipid signaling molecules share interesting properties and suggest that they constitute a large set of signal control and transduction mechanisms that include, but range far beyond, the classical steroid hormone signaling mechanism. Juvenile hormone is the insect representative of this widespread and diverse system of lipid signaling molecules that regulate protein activity in a variety of ways. We propose a synthetic perspective for understanding juvenile hormone action in light of other lipid signaling systems and suggest that lipid activation of proteins has evolved to modulate existing signal activation and transduction mechanisms in animals and plants. Since small lipids can be inserted into many different pathways, lipid-activated proteins have evolved to play a great diversity of roles in physiology and development.     

The activity of the corpora allata in the fourth and fifth larval instars of the migratory locust

The presence of juvenile hormone in the haemolymph of larvae of Locusta has been detected by a modified Galleria bioassay and these results are compared with indirect methods of estimating corpus allatum activity. Juvenile hormone is present in the haemolymph during the fourth larval instar except on the last day of the instar, and is absent from the haemolymph of the fifth and final larval instar except on the last day of the instar. Changes in the volumes of the corpora allata simply reflect changes in the growth of the whole insect and are of no value in predicting endocrine activity. Changes in the size of the cells of the corpora allata can be correlated with the presence of juvenile hormone in the haemolymph in the fourth larval instar, but similar changes in cell size occur in the fifth larval instar when no juvenile hormone is present in the haemolymph. The effects of the implantation of corpora allata are unreliable as estimates of corpus allatum activity as isolated corpora allata from fifth instar larvae release juvenile hormone. Indirect methods of measuring corpus allatum activity are thus shown to be unreliable. The R_f value of Locusta juvenile hormone as determined by thin-layer chromatography differs from that of Roeller's juvenile hormone, suggesting that the two hormones might be chemically distinct.     

Effects of three compounds with anti-juvenile hormone activity and a juvenile hormone analogue on endogenous juvenile hormone levels in the tobacco hornworm, Manduca sexta

The ability of three anti-juvenile hormones and one juvenile hormone analogue to reduce in vivo juvenile hormone levels in Manduca sexta has been investigated. Two compounds. FMev (tetrahydro-4-fluoromethyl-4-hydroxy-2H-pyran-2-one) and ETB (ethyl-4-[2-(tert-butylcarbonyloxy)butoxy]-benzoate) reduced the titres of juvenile hormones I and II to near the levels of detection in topically treated larvae. Precocene III (7-ethoxy-6-methoxy-2,2-dimethylchromene) was inactive but the juvenile hormone analogue hydroprene was as effective as the two anti-juvenile hormones in reducing endogenous juvenile hormone titres in larvae. FMev was also shown to reduce the level of juvenile hormones II and III in pharate adults.