Sequential gene activation by ecdysone in polytene chromosomes of Drosophila melanogaster. VI. Inhibition by juvenile hormones

Glue protein production can be triggered by steroid hormone signaling independent of the developmental program in Drosophila melanogaster

Steroid hormones regulate life stage transitions, allowing animals to appropriately follow a developmental timeline. During insect development, the steroid hormone ecdysone is synthesized and released in a regulated manner by the prothoracic gland (PG) and then hydroxylated to the active molting hormone, 20-hydroxyecdysone (20E), in peripheral tissues. We manipulated ecdysteroid titers, through temporally controlled over-expression of the ecdysteroid-inactivating enzyme, CYP18A1, in the PG using the GeneSwitch-GAL4 system in the fruit fly Drosophila melanogaster. We monitored expression of a 20E-inducible glue protein gene, Salivary gland secretion 3 (Sgs3), using a Sgs3:GFP fusion transgene. In wild type larvae, Sgs3-GFP expression is activated at the midpoint of the third larval instar stage in response to the rising endogenous level of 20E. By first knocking down endogenous 20E levels during larval development and then feeding 20E to these larvae at various stages, we found that Sgs3-GFP expression could be triggered at an inappropriate developmental stage after a certain time lag. This stage-precocious activation of Sgs3 required expression of the Broad-complex, similar to normal Sgs3 developmental regulation, and a small level of nutritional input. We suggest that these studies provide evidence for a tissue-autonomic regulatory system for a metamorphic event independent from the primary 20E driven developmental progression.

Effect of exogenous hormones on transcription levels of pyridoxal 5'-phosphate biosynthetic enzymes in the silkworm (Bombyx mori)

Vitamin B6 includes 6 pyridine derivatives, among which pyridoxal 5'-phosphate is a coenzyme for over 140 enzymes. Animals acquire their vitamin B6 from food. Through a salvage pathway, pyridoxal 5'-phosphate is synthesized from pyridoxal, pyridoxine or pyridoxamine, in a series of reactions catalyzed by pyridoxal kinase and pyridoxine 5'-phosphate oxidase. The regulation of pyridoxal 5'-phospahte biosynthesis and pyridoxal 5'-phospahte homeostasis are at the center of study for vitamin B6 nutrition. How pyridoxal 5'-phosphate biosynthesis is regulated by hormones has not been reported so far. Our previous studies have shown that pyridoxal 5'-phosphate level in silkworm larva displays cyclic developmental changes. In the current study, effects of exogenous juvenile hormone and molting hormone on the transcription level of genes coding for the enzymes involved in the biosynthesis of pyridoxal 5'-phospahte were examined. Results show that pyridoxal kinase and pyridoxine 5'-phosphate oxidase are regulated at the transcription level by development and are responsive to hormones. Molting hormone stimulates the expression of genes coding for pyridoxal kinase and pyridoxine 5'-phosphate oxidase, and juvenile hormone appears to work against molting hormone. Whether pyridoxal 5'-phosphate biosynthesis is regulated by hormones in general is an important issue for further studies.

Ecdysone receptors: from the Ashburner model to structural biology

In 1974, Ashburner and colleagues postulated a model to explain the control of the puffing sequence on Drosophila polytene chromosomes initiated by the molting hormone 20-hydroxyecdysone. This model inspired a generation of molecular biologists to clone and characterize elements of the model, thereby providing insights into the control of gene networks by steroids, diatomic gases, and other small molecules. It led to the first cloning of the EcR subunit of the heterodimeric EcR-USP ecdysone receptor. X-ray diffraction studies of the ligand-binding domain of the receptor are elucidating the specificity of receptor-ecdysteroid interactions, the selectivity of some environmentally friendly insecticides, the evolution of the EcR-USP heterodimer, and indeed Ashburner's classical biochemical evidence for the central role of the ecdysone receptor in his model.

The Drosophila FTZ-F1 nuclear receptor mediates juvenile hormone activation of E75A gene expression through an intracellular pathway

Juvenile hormone (JH) regulates a wide variety of biological activities in holometabolous insects, ranging from vitellogenesis and caste determination in adults to the timing of metamorphosis in larvae. The mechanism of JH signaling in such a diverse array of processes remains either unknown or contentious. We previously found that the nuclear receptor gene E75A is activated in S2 cells as a primary response to JH. Here, by expressing an intracellular form of JH esterase, we demonstrate that JH must enter the cell in order to activate E75A. To find intracellular receptors involved in the JH response, we performed an RNAi screen against nuclear receptor genes expressed in this cell line and identified the orphan receptor FTZ-F1. Removal of FTZ-F1 prevents JH activation of E75A, whereas overexpression enhances activation, implicating FTZ-F1 as a critical component of the JH response. FTZ-F1 is bound in vivo to multiple enhancers upstream of E75A, suggesting that it participates in direct JH-mediated gene activation. To better define the role of FTZ-F1 in JH signaling, we investigated interactions with candidate JH receptors and found that the bHLH-PAS proteins MET and GCE both interact with FTZ-F1 and can activate transcription through the FTZ-F1 response element. Removal of endogenous GCE, but not MET, prevents JH activation of E75A. We propose that FTZ-F1 functions as a competence factor by loading JH signaling components to the promoter, thus facilitating the direct regulation of E75A gene expression by JH.

Heterodimer of two bHLH-PAS proteins mediates juvenile hormone-induced gene expression

Juvenile hormone (JH) plays crucial roles in many aspects of insect life. The Methoprene-tolerant (Met) gene product, a member of the bHLH-PAS family of transcriptional regulators, has been demonstrated to be a key component of the JH signaling pathway. However, the molecular function of Met in JH-induced signal transduction and gene regulation remains to be fully elucidated. Here we show that a transcriptional coactivator of the ecdysteroid receptor complex, FISC, acts as a functional partner of Met in mediating JH-induced gene expression. Met and FISC appear to use their PAS domains to form a dimer only in the presence of JH or JH analogs. In newly emerged adult female mosquitoes, expression of some JH responsive genes is considerably dampened when Met or FISC is depleted by RNAi. Met and FISC are found to be associated with the promoter of the early trypsin gene (AaET) when transcription of this gene is activated by JH. A juvenile hormone response element (JHRE) has been identified in the AaET upstream regulatory region and is bound in vitro by the Met-FISC complex present in the nuclear protein extracts of previtellogenic adult female mosquitoes. In addition, the Drosophila homologs of Met and FISC can also use this mosquito JHRE to activate gene transcription in response to JH in a cell transfection assay. Together, the evidence indicates that Met and FISC form a functional complex on the JHRE in the presence of JH and directly activate transcription of JH target genes.

Farnesoid secretions of dipteran ring glands: what we do know and what we can know

Harnessing of the Drosophila genetic system toward ascertaining the molecular endocrinology of higher dipteran (cyclorrhaphan) larval development has been a goal for over 70 years, beginning with the data left to us by pioneer researchers from the classical endocrine era. The results of their experiments evidence numerous ring gland activities that are parsimoniously explained as arising from secretions of the larval corpora allatal cells. Utilization of those data toward an understanding of molecular endocrinology of cyclorrhaphan metamorphosis has not yet achieved its hoped for fruition, in part due to a perceived difficulty in identifying larval targets of the molecule "methyl epoxyfarnesoate" (=juvenile hormone III). However, as is reviewed here, it is important to maintain a conceptual distinction between "the target of JH III"Versus "the target(s) of products secreted by the larval corpora allatal cells of ring glands." Recent advances have been made on the identity, regulation and reception of ring gland farnesoid products. When these advances are evaluated together with the above data from the classical endocrine era, there is a new opportunity to frame experimental hypotheses so as to discern underlying mechanisms on cyclorrhaphan larval-pupal metamorphosis that have been heretofore intractable. This paper reconsiders a number of evidenced physiological targets of secretions of corpora allatal cells of the larval ring gland, and places them in the context of more recent biochemical and molecular advances in the field.

Gene expression in pyriproxyfen-resistant Bemisia tabaci Q biotype

Pyriproxyfen is a biorational insecticide that acts as a juvenile hormone (JH) analogue and disrupts insect development with an unknown molecular mode of action. Pyriproxyfen is one of the major insecticides used to control the whitefly Bemisia tabaci (Gennadius) and comply with integrated pest management (IPM) programmes, resulting in minimal effects on the environment, humans and beneficial organisms. During the last few years, resistance to pyriproxyfen has been observed in several locations in Israel, sometimes reaching a thousandfold or more. No information exists about the molecular basis underlying this resistance that may lead to understanding the mode of action of pyriproxyfen and developing molecular markers for rapid monitoring of resistance outbreaks. In this communication, a cDNA microarray from B. tabaci was used to monitor changes in gene expression in a resistant B. tabaci population. Based on statistical analysis, 111 expressed sequence tags (ESTs) were identified that were differentially upregulated in the resistant strain after pyriproxyfen treatment. Many of the upregulated ESTs observed in the present study belong to families usually associated with resistance and xenobiotic detoxification such as mitochondrial genes, P450s and oxidative stress, genes associated with protein, lipid and carbohydrate metabolism and others related to JH-associated processes in insects such as oocyte and egg development.

Specific transcriptional responses to juvenile hormone and ecdysone in Drosophila

Previous studies have shown that ecdysone (E), and its immediate downstream product 20-hydroxyecdysone (20E), can have different biological functions in insects, suggesting that E acts as a distinct hormone. Here, we use Drosophila larval organ culture in combination with microarray technology to identify genes that are transcriptionally regulated by E, but which show little or no response to 20E. These genes are coordinately expressed for a brief temporal interval at the onset of metamorphosis, suggesting that E acts together with 20E to direct puparium formation. We also show that E74B, pepck, and CG14949 can be induced by juvenile hormone III (JH III) in organ culture, and that CG14949 can be induced by JH independently of protein synthesis. In contrast, E74A and E75A show no response to JH in this system. These studies demonstrate that larval organ culture can be used to identify Drosophila genes that are regulated by hormones other than 20E, and provide a basis for studying crosstalk between multiple hormone signaling pathways.

Can juvenogens, biochemically targeted hormonogen compounds, assist in environmentally safe insect pest management?

Two different types of juvenogens, biochemically targeted hormonogen compounds were tested for their potency to act as insect pest management agents. In the performed biological screening, wax-like esteric juvenogens (3-10) proved to be convenient agents for controlling blowfly and termites, and displayed species selectivity: cis-N-{2-[4-(2-butanoyloxycyclohexyl)methyl]phenoxy}ethyl carbamate (3) was highly active on blowfly (Neobellieria bullata), while trans-N-{2-[4-(2-hexadecanoyloxycyclohexyl)methyl]-phenoxy}ethyl carbamate (6) showed high activity on termite (Prorhinotermes simplex). Glycosidic juvenogens, isomeric N-{2-{4-{[2-(beta-D-galactopyranosyloxy)cyclohexyl]methyl}phenoxy}ethyl carbamates (13 and 14), were proved to act as systemic agents, suitable for protecting plants against phytophagous insects (e.g. aphids). Due to the prolonged action of juvenogens, which is connected with the sequential liberating of the biologically active molecule of the insect juvenile hormone bioanalog from the juvenogen molecule by means of enzymic systems of target insects and/or their host plants, more insect individuals can be treated by juvenogens, which are species-targeted structures due to their different physicochemical properties. The results achieved with both types of juvenogens were promising, concerning their final effect on the tested insect species, and the compounds 3-6, 9 (cis-(9Z)-N-{2-[4-(2-(octadec-9-enoyl)oxycyclohexyl)methyl]phenoxy}ethyl carbamate), 13 and 14 proved to represent convenient insect pest management agents for potential practical applications against different insect pests.

Hormonal regulation and functional role of Drosophila E75A orphan nuclear receptor in the juvenile hormone signaling pathway

Ecdysone and juvenile hormone (JH) are important regulators of insect growth and development. While ecdysone initiates a transition from one developmental stage to another, JH determines the nature of the transition. How these two hormones interact at the molecular level is not known. Here we report the JH inducibility of the E75A nuclear receptor encoded by the E75 early ecdysone-inducible gene. In Drosophila S2 cells, E75A transcription is specifically activated by JH at concentrations well within the physiological range found in larvae and adults. The induction is rapid and does not require a concurrent protein synthesis, and thus represents a primary hormone response. Consistent with JH regulation, E75A mRNA levels are reduced in ovaries of apterous(4) mutant adults defective in JH secretion. Expression is rescued by topical methoprene application. We further provide evidence that ectopic E75A is sufficient to perform several functions in the JH signaling pathway. First, it can down-regulate its own transcription. Second, E75A can potentiate the JH inducibility of a secondary response gene, JhI-21. Finally, in the presence of JH, E75A can repress ecdysone activation of early genes including Broad-Complex. Based on these data, we propose a model for the role of E75A in the ecdysone-JH regulatory interplay.

The molecular site of action of juvenile hormone and juvenile hormone insecticides during metamorphosis: how these compounds kill insects

Studies in a variety of insects during the past four decades has deepened our understanding of juvenile hormone (JH) physiology, but how this hormone works at the molecular level remains elusive. Similarly, the mechanism of toxicity of JH analogue insecticides is still in question. There is much evidence from laboratory usage that JHAs act as JH agonists and generally show the highest toxicity when applied at the onset of metamorphosis. A physiological basis for the toxicity and morphogenetic effects has been suggested by recent work linking these effects with interference with the expression or action of certain genes, particularly the Broad-Complex (BR-C) transcription factor gene, that direct metamorphic change. Misexpressed BR-C then leads to improper expression of one or more downstream effector genes controlled by BR-C gene products, resulting in abnormal developmental and physiological changes that disrupt metamorphosis. Therefore, JH is a necessary molecule at certain times in insect development but becomes toxic when present during metamorphosis.

Juvenile hormone potentiates ecdysone receptor-dependent transcription in a mammalian cell culture system

Insect development is guided by the combined actions of ecdysteroids and juvenile hormones (JHs). The transcriptional effects of ecdysteroids are mediated by a protein complex consisting of the ecdysone receptor (EcR) and its heterodimeric partner, Ultraspiracle (USP), but a corresponding JH receptor has not been defined conclusively. Given that the EcR ligand binding domain (LBD) is similar to that of the JH-responsive rat farnesoid-X-activated receptor (FXR), we sought to define experimental conditions under which EcR-dependent transcription could be promoted by JH. Chinese hamster ovary (CHO) cells were transfected with a plasmid carrying an ecdysteroid-inducible reporter gene, a second plasmid expressing one of the three amino-terminal variants of Drosophila EcR or an EcR chimera, and a third plasmid expressing either the mouse retinoid X receptor (RXR), or its insect orthologue, USP. Each of the EcR variants responded to the synthetic ecdysteroid, muristerone A (murA), but a maximal response to 20-hydroxyecdysone (20E) was achieved only for specific EcR combinations with its heterodimeric partner. Notably, the Drosophila EcR isoforms were responsive to 20E only when paired with USP, and only EcRB2 activity was further potentiated by JHIII in the presence of 20E. EcR chimeras that fuse the activator domains from VP16 or the glucocorticoid receptor to the Drosophila EcR DNA-binding and ligand-binding domains were responsive to ecdysteroids. Again, the effects of JHIII and 20E were associated with specific partners of the chimeric EcRs. In all experiments, the LBD of EcR proved to be the prerequisite component for potentiation by JHIII, and in this conformation may resemble the FXR LBD. Our results indicate that EcR responsiveness is influenced by the heterodimeric partner and that both the N-terminal domain of EcR and the particular ecdysteroid affect JHIII potentiation.

Swelling of mitochondria induced by juvenile hormone in larval salivary glands of Drosophila melanogaster

Treatment of Drosophila larval salivary glands with juvenile hormone or its analogues leads to ultrastructural changes of mitochondria that mimic those seen after application of uncouplers of oxidative phosphorylation. This alteration of mitochondria, also known as swelling, is manifested in strong dilatation of their intercristae space. The mitochondrial response of salivary glands to juvenile hormone is restricted to collum cells that are known to be ultrastructurally and functionally different from transitional and corpus cells and may reflect their specialization in energy metabolism and water/ion balance. Morphological change of mitochondria and about a fivefold increase in cytochrome c oxidase activity in response to juvenile hormone appear to be a consequence of uncoupling of oxidative phosphorylation. We have noticed no significant difference of the responses in Methoprene, the juvenile hormone resistant mutant, suggesting that this action of juvenile hormone may be mediated via a mechanism different from that using nuclear transcription factors. The "uncoupling" effect is caused also by juvenile hormone analogues which are considered inactive in producing morphogenetic effects in Drosophila. Mitochondrial response is independent of transcription and translation, as revealed by the use of RNA and protein synthesis inhibitors. Given these data together, we reasoned that the protonophoric/uncoupling effect of juvenile hormone is a cell type specific nongenomic response to this lipophilic ligand and contrasts with widely accepted notions about nuclear action of juvenile hormone.

The isolation of two juvenile hormone-inducible genes in Drosophila melanogaster

Juvenile hormone (JH) is an important regulator of both insect development and reproductive maturation. Although the molecular mechanism of JH action is not yet known, there is growing circumstantial evidence that JH directly regulates gene expression. In the absence of a JH target gene, however, this suggestion has remained speculative. Cultured Drosophila S2 cells have been used to identify genes whose expression is regulated by JH. Employing differential display we identified several genes whose transcripts accumulate in cells treated with the JH agonist methoprene. Two of the genes-JhI-1 and JhI-26-were cloned and characterized in detail. For both genes, transcripts showed rapid and specific induction in the presence of either methoprene or JHIII, but not in the presence of other biologically inactive compounds of similar chemical structure. Accumulation of JhI-1 and JhI-26 RNAs requires continuous hormone presence. The developmental expression of the two JH-inducible genes corresponds to the abundance profile of JH in vivo. Furthermore, topical methoprene application to pupae leads to the ectopic accumulation of JhI-1 and JhI-26 transcripts.

A juvenile hormone agonist reveals distinct developmental pathways mediated by ecdysone-inducible broad complex transcription factors

Juvenile hormone (JH) is an important regulator of insect development that, by unknown mechanisms, modifies molecular, cellular, and organismal responses to the molting hormone, 20-hydroxyecdysone (20E). In dipteran insects such as Drosophila, JH or JH agonists, administered at times near the onset of metamorphosis, cause lethality. We tested the hypothesis that the JH agonist methoprene acts by interfering with function of the Broad Complex (BRC), a 20E-regulated locus encoding BTB/POZ-zinc finger transcription factors essential for metamorphosis of many tissues. We found that methoprene, administered by feeding or by topical application, disrupts the metamorphic reorganization of the central nervous system, salivary glands, and musculature in a dose-dependent manner. As we predicted, methoprene phenocopies a subset of previously described BRC defects; it also phenocopies Deformed and produces abnormalities not associated with known mutations. Interestingly, methoprene specifically disrupts those metamorphic events dependent on the combined action of all BRC isoforms, while sparing those that require specific isoform subsets. Thus, our data provide independent pharmacological evidence for the model, originally based on genetic studies, that BRC proteins function in two developmental pathways. Mutations of Methoprene-tolerant (Met), a gene involved in the action of JH, protect against all features of the "methoprene syndrome." These findings have allowed us to propose novel alternative models linking BRC, juvenile hormone, and MET.

Juvenile hormone prevents ecdysteroid-induced expression of broad complex RNAs in the epidermis of the tobacco hornworm, Manduca sexta

A cDNA homolog of the Drosophila melanogaster Broad Complex (BRC) gene was isolated from the tobacco hornworm, Manduca sexta, which shows a predicted 88% amino acid identity with Drosophila BRC in the N-terminal BTB domain. Three zinc finger domains encoding homologs of the Drosophila Z2, Z3, and Z4 domains (93, 100, and 85% identity, respectively) were obtained by RT-PCR. In Manduca dorsal abdominal epidermis, BRC RNAs were not observed during the larval molt. Three BRC transcripts-6.0, 7.0, and 9.0 kb-first appeared at the end of the feeding stage of the fifth (final) instar when the epidermis is exposed to ecdysteroids in the absence of juvenile hormone (JH) and becomes committed to pupal differentiation. These RNAs were induced in day 2 fifth larval epidermis in vitro by 20-hydroxyecdysone (20E) in the absence of JH with dose-response and time courses similar to the induction of pupal commitment. This induction by 20E in vitro was prevented by the presence of JH I at levels seen in vivo during the larval molt. In the wing discs, the BRC RNAs appeared shortly after ecdysis to the fifth instar and coincided with the onset of metamorphic competence of these discs. Application of a JH analogue pyriproxifen during the fourth instar molt delayed and reduced the levels of BRC mRNAs seen in the wing discs in the early fifth instar, but did not completely prevent their appearance in this tissue that first differentiates at metamorphosis. The expression of the BRC transcription factors thus appears to be one of the first molecular indications of the genetic reprogramming of the epidermis necessary for insect metamorphosis. How JH prevents BRC expression in this epidermis may provide the key to understanding how this hormone controls metamorphosis.

Identification of regulatory sequences of juvenile hormone-sensitive and -insensitive serum protein-encoding genes

The promoters of three juvenile hormone (JH)-sensitive, and one JH-insensitive hexamerin-encoding genes (Hex) were isolated from Trichoplusia ni, and sequences necessary for, or affecting, transcriptional activity were identified by biochemical and functional methods. The transcription start points (tsp) for each of the four Hex were determined biochemically, by both primer extension and the sequencing of multiple, independent full-length cDNA clones. The function of each inferred tsp, as an actual tsp, was confirmed by in vitro transcription assay. The transcription initiator sequence, GNACAGT, was identical for three of the Hex, while the fourth used a divergent motif. Using the in vitro transcription system, a minimal core promoter of 60 bp (bp -34 to +24) of the BJHSP1 (basic JH suppressible protein 1) gene, containing a single TATA box motif approximately 30 bp upstream of the tsp, was functionally sufficient to support alpha-amanitin-sensitive transcription. The same construct was also transcriptionally functional in a homologous cell line transfection assay. The corresponding region of the other Hex also contains a similarly positioned TATA box motif, and promoter constructs for each, that included that included the tsp, initiator and inferred basal transcription apparatus binding site, were all transcriptionally functional in a cell line transfection assay. The action of sequences 5' to the minimal promoter region in modulating the rate of transcription was shown by a cell line transfection assay of a nested deletion series of the promoter for the BJHSP1 gene, in which the results identified a strongly suppressive element between positions -160 and -109. This system of Hex genes, including those sensitive to JH and one not sensitive, should be useful in a comparative approach toward identifying those regulatory motifs that are functionally necessary to transduce the regulatory action of JH.

Insect nuclear receptors: a developmental and comparative perspective

The appearance of puffs on the polytene chromosomes of insect salivary glands incubated with 20-hydroxyecdysone provided the first demonstration that steroids act directly at the gene transcriptional level to bring about subsequent cellular changes (Becker, 1959; Clever and Karlson, 1960). Despite that auspicious beginning, learning about the molecular mechanisms that underlie the hormonal regulation of insect development was impeded for many years by the difficulty associated with isolating and identifying rare regulatory factors from limited tissue sources. The advent of recombinant DNA methodology and powerful techniques such as the polymerase chain reaction (PCR) along with the recognition that many important endocrine factors are structurally conserved across a wide range of species has, however, all but eliminated the technical obstacles once facing the insect endocrinologist trying to isolate and study these regulatory molecules. This review will discuss recent progress and recall some earlier experiments concerning the molecular basis of hormonal action in insects focusing primarily on the members of the nuclear hormone receptor superfamily in Drosophila melanogaster. Two members of this family comprise the functional ecdysteroid receptor and at least a dozen other "orphans" have been identified in Drosophila for which no cognate ligand has yet been found. Many of these orphans are regulated by ecdysteroids. A discussion of juvenile hormone binding proteins that are not family members has been included because of their potential impact on nuclear receptor function. As receptor homologues have been identified in other insects, several general ideas concerning insect hormonal regulation have begun to emerge and these will be examined from a comparative point of view.

The juvenile hormone analogue, methoprene, inhibits ecdysterone induction of small heat shock protein gene expression

The small heat shock protein (hsp) genes of Drosophila are expressed in cultured cells in response to the moulting hormone, ecdysterone. We show here that juvenile hormone (JHIII) and the juvenile hormone analogue, methoprene, inhibit that induction in a dose-dependent manner. Heat shock induction is not inhibited. In transient expression studies using S3 line cells transfected with EcRE-CAT constructs, methoprene inhibition was found to require a 2-hr pretreatment (before ecdysterone addition), and methoprene's continued presence was essential. Farnesol, farnesyl acetate, and retinoic acid did not cause inhibition. Several models of methoprene inhibition are discussed.

Effects of juvenile hormone on the ecdysone response of Drosophila Kc cells

Drosophila Kc cells are ecdysone-responsive: hormone treatment leads rapidly to increased synthesis of several ecdysone-inducible polypeptides (EIPs) and to commitment to eventual proliferative arrest. Later, the treated cells undergo morphological transformation, cease to proliferate, and develop new enzymatic activities, notably, acetylcholinesterase (AChE) activity. These responses have proven useful as models for studying ecdysone action. Here we report the sensitivity of Kc cells to another important insect developmental regulator--juvenile hormone (JH). We find that JH inhibits some, but not all, aspects of the ecdysone response. When Kc cells are treated with ecdysone in the presence of either natural JHs or synthetic analogues, the morphological and proliferative responses are inhibited and AChE induction is blocked. Most striking is that JHs protect the cells from the rapid proliferative commitment induced by ecdysone alone. The JH effects exhibit reasonable dose-response curves with half-maximal responses occurring at very low JH concentrations. Nonetheless, even at high JH concentrations the inhibitory effects are incomplete. It is interesting that EIP induction appears to be refractory to JH. It seems clear that JH is not simply a generalized inhibitor of ecdysone-induced responses.

Genetics of esterases in Drosophila. IX. Characterization of the JH-esterase in D. virilis

The kinetic characteristics of the main isozymes of Drosophila virilis esterase were studied and Km values of esterase-2, -4, and -6 and p-esterase for alpha- and beta-naphthyl acetate were obtained. Juvenile hormone (JH) was shown to inhibit the p-esterase activity when in competition with beta-naphthyl acetate and the general esterase inhibitor, diisopropylphosphofluoridate (DFP), was shown to inhibit all the components of the D. virilis esterase patterns except p-esterase. While studying the changes of p-esterase activity in D. virilis ontogenesis, the increase in p-esterase activity in the wandering larvae, prepupae, and early pupae was found to correlate with a decrease in JH titer at these stages. The decrease in JH level in a temperature-sensitive lethal mutant larvae of D. virilis at high temperatures was shown to correlate with increased p-esterase activity. These results confirm that p-esterase of D. virilis is JH-esterase.

Electron microscopical analysis of Drosophila polytene chromosomes. II. Development of complex puffs

Data are presented of electron microscopic (EM) analysis of consecutive developmental stages of Drosophila melanogaster complex puffs, formed as a result of simultaneous decondensation of several bands. EM mapping principles proposed by us permitted more exact determination of the banding patterns of 19 regions in which 31 puffs develop. It is shown that 20 of them develop as a result of synchronous decondensation of two bands, 7 of three and 4 of one band. Three cases of two-band puff formation when one or both bands undergo partial decondensation are described. In the 50CF, 62CE, 63F and 71CF regions puffing zones are located closely adjacent to each other but the decondensation of separate band groups occurs at different puff stages (PS). These data are interpreted as activation of independently regulated DNA sequences. The decondensation of two or three adjacent bands during formation of the majority of the puffs occurs simultaneously in the very first stages of their development. It demonstrates synchronous activation of the material of several bands presumably affected by a common inductor. Bands adjacent to puffing centres also lose their clarity as the puff develops, probably due to "passive" decondensation connected with puff growth. The morphological data obtained suggest a complex genetic organisation of many puffs.

Replication of Drosophila chromosomes. IX. Stimulation of initiation of polytene replication cycles in vitro by juvenile hormone

A greater proportion of polytene nuclei show [3H]thymidine incorporation when third instar larval salivary glands of Drosophila nasuta are pulse-labelled after in vitro culture (3-24 h) in the presence of a juvenile hormone mimic, ZR 515. In glands chronically labelled with [3H]thymidine in the presence of ZR 515, more nuclei are seen to have entered new polytene replication cycles. Similarly, when salivary glands from larvae fed on 5-fluorodeoxyuridine to block polytene replication cycles at intersynthetic periods were cultured in vitro, new polytene replication cycles were initiated more quickly in the presence of ZR 515. These results suggest a stimulatory effect of juvenile hormone on new polytene replication cycles.

mRNA populations during wing development in the silkmoth Antheraea polyphemus

Pupal wing tissue of the American silkmoth Antheraea polyphemus has been used as a model system to study 20-hydroxyecdysone and juvenile hormone control of cuticle protein synthesis. Juvenile hormone does not affect either the content or rate of synthesis of RNA and protein of the wing tissue. both of which show linear increases during the first few days of hormonal treatment. Based on the fractionation of total RNA on oligo-dT columns the percent of mRNA remains the same throughout development after both hormone treatments. However, both the amount of poly-A+ RNA in the wing tissue, and its content of poly-A show considerable increases as a function of development. The products of translation of the various poly-A+ RNA populations in the cell-free wheatgerm system have been analyzed by one- and two-dimensional gel electrophoresis and fluorography. Qualitative changes occur during the first 24 h; the production of a mRNA coding for a protein of approx. 40 000 dalton is stimulated and the production of a mRNA coding for a protein of 29 000 dalton is greatly reduced. Only a few differences are observed between samples from the 2 hormone treatments. Over the next 5-15 days of development mainly quantitative changes are observed. Juvenile hormone application results in quantitative changes in specific mRNAs, but no new mRNAs unique to juvenile hormone action are observed. The data are consistent with the concept that in altering the epidermal developmental program, juvenile hormone is apparently modulating the action of 20-hydroxyecdysone.

A critical period of ecdysterone action on sensitive clones of Drosophila cultured in vitro: the maturation of the cells

Ecdysterone-sensitive clones cultured in vitro were isolated from established cell lines of Drosophila melanogaster. The clones FC and 89K are ecdysterone-inducible for two enzymatic activities: acetylcholinesterase and beta-galactosidase. No activity could be detected in untreated cells, whereas after treatment with 50-250 nM ecdysterone, the activity appeared after one day and increased during 3-4 days. We wanted to modulate the response of the cells by varying the conditions of the hormonal stimulus. Mimicking the physiological situation of Drosophila (the ecdysterone peak corresponding to the molts is preceded by low levels) we pretreated the cells with a subthreshold concentration (1-5 nM) for 2 days and then we added the stimulating concentration of 50-250 nM ecdysterone. The enzymatic activities were then detectable within the following hours and the final level of induction was about twice the one of cells without pretreatment. Thus, the continuous presence of a subthreshold concentration of ecdysterone provokes the maturation of the cells which become able to respond to the hormonal stimulus by a quicker and higher enzymatic induction. The cellular maturation seems to be a critical period. It is altosid-sensitive. Altosid (a juvenile hormone analog) abolishes the effects of the ecdysterone-induced maturation.