Larval cuticular morphogenesis in the tobacco hornworm, Manduca sexta, and its hormonal regulation

Site of synthesis and phylogenetic distribution of a hemolymph trophic factor of the tobacco hornworm, Manduca sexta

Identification of fifth instar larval Manduca sexta fat body and epidermis as sites of synthesis of a hemolymph protein (hemolymph trophic factor or HTF) was achieved using in vitro 3H-leucine incorporation into protein and subsequent immunoprecipitation of tissue homogenates. Fat body is the primary site of HTF synthesis with a maximal rate on Day 1; epidermis is a secondary site with peak synthesis on Day 0. In vitro radiolabelling followed by TCA precipitation of general protein of fat body and epidermal homogenates suggest that fat body actively elaborates protein on Days 0-5 with peak rates on Days 1 and 4, while epidermis is active on Days 0-5 with a peak rate on Day 3. Based on Anti-HTF ELISA estimates, HTF [500 to 1000 micrograms/ml] was found in the hemolymph of representatives of the insect orders Blattodea, Hemiptera, Orthoptera, and Lepidoptera and in the class Crustacea, but not in the class Merostomata. These studies suggest a possible fundamental role for HTF among modern arthropods in cuticular deposition involving both epidermis and fat body. The physiological role of HTF is undetermined.

Characterization of two high molecular weight catechol-containing glycoproteins from pharate pupal cuticle of the tobacco hornworm, Manduca sexta

Two high molecular weight cuticular proteins (MSCP120 and MSCP246) were extracted in acidic guanidine hydrochloride solution from tanning abdominal cuticle of Manduca sexta pharate pupae and purified by size exclusion high performance liquid chromatography. The apparent molecular weights were ca. 120 and 246 kDa as determined by sodium dodecyl sulfate polyacrylamide gel electrophoresis. Both proteins contained high levels of glutamate/glutamine, glycine, serine, alanine and aspartate/asparagine. MSCP120 was enriched in histidine relative to MSCP246, but the reverse was true for valine and proline. Small quantities of beta-alanine and 3,4-dihydroxyphenylalanine (DOPA), as well as other catechols and carbohydrates, also were detected in the hydrolysates. The proteins became radiolabeled when [1-14C]-beta-alanine was injected into pharate pupae, presumably by the formation of adducts with N-beta-alanyldopamine metabolites during sclerotization. Mild acid hydrolysis released N-beta-alanylnorepinephrine and 3,4-dihydroxyphenylketoethanol from both proteins. Strong acid hydrolysis yielded predominantly 3,4-dihydroxyphenylketoethylamine (arterenone), but also DOPA and dopamine. The N-terminal amino acid sequences of the two cuticular proteins were dissimilar, and that of MSCP246 was more hydrophobic than MSCP120. Both of these proteins were glycosylated with glucose, N-acetylglucosamine and traces of N-acetylgalactosamine, and MSCP246 also contained galactose. These structural glycoproteins, which occur in cuticle undergoing sclerotization, apparently react post-translationally with quinonoid tanning agents to yield catecholamine-protein adducts. Small amounts of peptidyl DOPA probably are formed by hydroxylation of tyrosyl residues. Results from this study are consistent with the hypothesis that these catechol-containing glycoproteins participate in cross-linking reactions in M. sexta pupal cuticle during sclerotization.

Characterization of four pupal wing cuticular protein genes of the silkmoth Antheraea polyphemus

Three different clones have been isolated from a genomic library of the silkmoth Antheraea polyphemus by employing a subtractive hybridization technique. The clones with inserts of 13-16 kb of DNA each, code for mRNAs expressed in the wing epidermis during JH induced second pupal cuticle deposition. While two of the clones code for a single mRNA each, the third one codes for two mRNAs. All the four mRNAs code for distinct polypeptides that can be precipitated with antibodies raised against pupal cuticular proteins. These genes are activated at the same period of pupal development and their transcripts follow similar patterns of accumulation. Although these genes are expressed in a tissue and time specific manner attesting to their pupal wing epidermal specificity, three of them are expressed in the adult wing epidermis also, but not at the larval stage. While DNAs from other silkmoths and insects hybridize to these genes, only one of the A. polyphemus genes hybridizes to RNA from second pupal wings of two other silkmoths tested.

Ecdysone receptor expression in the CNS correlates with stage-specific responses to ecdysteroids during Drosophila and Manduca development

In insects, the ecdysteroids act to transform the CNS from its larval to its adult form. A key gene in this response is the ecdysone receptor (EcR), which has been shown in Drosophila to code for 3 protein isoforms. Two of these isoforms, EcR-A and EcR-B1, are prominently expressed in the CNS and we have used isoform-specific antibodies to examine their fluctuations through postembryonic life. EcR expression at the onset of metamorphosis is extremely diverse but specific patterns of EcR expression correlate with distinct patterns of steroid response. Most larval neurons show high levels of EcR-B1 at the start of metamorphosis, a time when they lose larval features in response to ecdysteroids. Earlier, during the larval molts, the same cells have no detectable receptors and show no response to circulating ecdysteroids; later, during the pupal-adult transformation, they switch to EcR-A expression and respond by maturing to their adult form. During the latter period, a subset of the larval neurons hyperexpress EcR-A and these cells are fated to die after the emergence of the adult. The stem cells for the imaginal neurons show prominent EcR-B1 expression during the last larval stage correlated with their main proliferative period. Most imaginal neurons, by contrast, express only EcR-A when they subsequently initiate maturation at the start of metamorphosis. The imaginal neurons of the mushroom bodies are unusual amongst imaginal neurons in expressing the B1 isoform at the start of metamorphosis but they also show regressive changes at this time as they lose their larval axons. Imaginal neurons of the optic lobe show a delayed expression of EcR-B1 through the period when cell-cell interactions are important for establishing connections within this region of the CNS. Overall, the appearance of the two receptor isoforms in cells correlates with different types of steroid responses: EcR-A predominates when cells are undergoing maturational responses whereas EcR-B1 predominates during proliferative activity or regressive responses. The heterogeneity of EcR expression at the start of metamorphosis presumably reflects the diverse origins and requirements of the neurons that nevertheless are all exposed to a common hormonal signal.

Temporal synthesis of cuticle proteins during larval development in Glossina morsitans

1. Larval development in Glossina species occurs in utero with the mature third instar larva being deposited after a developmental period of 7 days. 2. In this study, the patterns of cuticular protein synthesis during larval development were analysed by two-dimensional gel electrophoresis. 3. From the results, four types of cuticle proteins were identified: those specific to larval, pupal and adult cuticles, and others common to all the stages. 4. Few cuticular proteins were synthesized between the first and second larval instars. By the third larval instar (two days before larviposition), a large number of proteins (Mr < or = 30 kDa) were induced. These proteins persisted up to the brown pupal stage and showed a rapid decline thereafter. Most of the proteins with molecular weights Mr < or = 30 kDa were undetectable at apolysis (5 days after larviposition). 5. By day 15 of the pupal stage, the number of cuticle proteins was very small. The protein profile during the pupal stages remained relatively constant. This was probably due to the fact that the pupal cuticle does not provide any protection since it is itself enclosed at all times within the protective puparium.

Ultrastructure of prothoracic glands during larval-pupal development of the tobacco hornworm, Manduca sexta: a reappraisal

The structure of Manduca sexta prothoracic glands was investigated using a protocol that preserves membranes. During the last larval stadium, prothoracic gland cells increase in diameter, volume, protein content, and perhaps number, enhancing their capacity to produce ecdysteroids. The glands' strand-of-cells morphology, their in situ location, the presence of gap junctions between cells, and junctional foot-like structures within cells support previous findings that prothoracicotropic hormone stimulates ecdysteroidogenesis via Ca(2+)-induced Ca2+ release. A different method of tissue fixation from that previously used to investigate the ultrastructure of Manduca sexta prothoracic glands has revealed a significantly different ultrastructure. These new findings begin to define roles for endoplasmic reticulum and mitochondria in ecdysteroid synthesis and support the hypothesis that the glands secrete the steroid hormone via exocytosis. The structural dynamics of the glands are discussed in the context of the glands' function during Manduca sexta larval-pupal development.

Effects of a protein synthesis inhibitor on the hormonally mediated regression and death of motoneurons in the tobacco hornworm, Manduca sexta

The larval-pupal transformation of Manduca sexta is accompanied by the loss of the abdominal prolegs. The proleg muscles degenerate, the dendritic arbors of proleg motoneurons regress, and a subset of the proleg motoneurons dies. The regression and death of proleg motoneurons are triggered by the prepupal peak of ecdysteroids in the hemolymph. To investigate the possible involvement of protein synthesis in these events, we gave insects repeated injections of the protein synthesis inhibitor, cycloheximide (CHX), during the prepupal peak. Examination of insects 3-5 days following CHX treatment showed that CHX inhibited the death of proleg motoneurons and the production of pupal cuticle in a dose-dependent fashion. When insects were allowed to survive for 10 days after the final CHX injection, motoneuron death and pupal cuticle production sometimes occurred belatedly, apparently in response to the ecdysteroid rise that normally triggers adult development. CHX treatments that inhibited motoneuron death were less effective in inhibiting dendritic regression in the same neurons. In another set of experiments, abdomens were isolated from the ecdysteroid-secreting glands prior to the prepupal peak, and infused with 20-hydroxyecdysone (20-HE). Single injections of CHX delivered just prior to the start of the 20-HE infusion inhibited motoneuron death and pupal cuticle production, but in the range of doses tested, did not prevent dendritic regression. Our findings suggest that protein synthesis is a required step in the steroid-mediated death of proleg motoneurons, and that dendritic regression is less susceptible to inhibition by CHX than is motoneuron death.

Developmental changes in cyclic AMP-dependent protein kinase associated with increased secretory capacity of Manduca sexta prothoracic glands

In Manduca sexta, basal and PTTH-stimulated secretion of ecdysteroids by prothoracic glands in vitro increases from days 1 to 4 of the fifth larval stage. Glandular content of cAMP-dependent protein kinase was analyzed to determine if the enzyme changes in concert with increased secretory response. Photoaffinity labeling with [32P]8-N3 cAMP revealed a 55-kDa cAMP-binding protein characteristic of the regulatory subunit of type-II cAMP-dependent protein kinase (RII). It appears that RII is one of a limited number of cellular proteins that is phosphorylated in the presence of [gamma-35S]ATP; the thiophosphorylated protein and the photoaffinity-labeled regulatory subunit possess the same M(r) and pI, and thiophosphorylation is blocked by mammalian cAMP-dependent protein kinase inhibitor. From days 1 to 4 of the fifth instar, glandular content of RII increases in conjunction with increased ecdysteroid secretory capacity. Application of JH analog on day 1 significantly inhibits the observed increase in RII. Catalytic subunit activity does not change from days 1 to 4 of the fifth instar, nor does cellular content of a 34-kDa protein previously shown to be phosphorylated in response to PTTH. While it is unlikely that increased content of RII is solely responsible for enhanced ecdysteroid secretion by the prothoracic glands, it may serve as a convenient marker for investigating the mechanism by which steroidogenic capacity is regulated.

Synthesis and secretion of low molecular weight cuticular proteins during heat shock in the tobacco hornworm, Manduca sexta

In the tobacco hornworm, Manduca sexta, heat shock normally elicits synthesis of the classic heat-shock proteins. A 1-hr heat shock of 42 degrees C and above can also increase the relative synthesis of certain 12-18 kD proteins in the epidermis. These 12-18 kD proteins were identified as cuticular proteins for several reasons. Like cuticular proteins, they appear only in the epidermis. They can be precipitated from epidermal homogenates with an antiserum to larval cuticle. The same conditions that increased labeled 12-18 kD proteins in the epidermis also increased labeled 12-18 kD proteins in the cuticle. Some of the epidermal increase may result from a partial inhibition of secretion to the cuticle during 46 degrees C heat shock, causing abnormal accumulation in the epidermis. However, slight increases also occur at lower temperatures, which do not inhibit secretion detectably. Preliminary results also indicate that total quantities of at least one cuticular protein mRNA may increase during heat shock, either because of increased transcription or increased mRNA stability.

cDNA cloning and deduced amino acid sequence of a major, glycine-rich cuticular protein from the coleopteran Tenebrio molitor. Temporal and spatial distribution of the transcript during metamorphosis

In Coleoptera, the elytra (forewings), with a very hard and thick cuticle, protect the membranous and delicate hindwings against mechanical stress. We have isolated and characterized a cDNA encoding a major cuticle protein in Tenebrio molitor, named ACP-20. The deduced amino acid sequence is roughly tripartite, with two terminal glycine-rich domains and a central region showing pronounced similarities with some other hard cuticle proteins. Northern blot and in situ hybridization analyses reveal that ACP-20 gene expression is developmentally regulated since transcript accumulation occurs only in epidermal regions synthesizing hard cuticle and is restricted to the period of preecdysial adult cuticle deposition. Moreover, application of a juvenile hormone analogue prevents the appearance of the transcript, indicating that juvenile hormone, a key molecule involved in the control of insect metamorphosis, negatively regulates the expression of the ACP-20 gene.

An ecdysteroid-inducible Manduca gene similar to the Drosophila DHR3 gene, a member of the steroid hormone receptor superfamily

Using cDNAs for the human retinoic acid receptor alpha (hRAR alpha) and Drosophila hormone receptor 3 (DHR3), we isolated a cDNA encoding a member of the steroid hormone receptor superfamily from the tobacco hornworm, Manduca sexta. Sequencing showed that this cDNA is most closely related to DHR3 (97 and 68% amino acid identity in the DNA and ligand binding regions, respectively) followed by hRAR alpha (65 and 20% identity, respectively) and therefore is named MHR3. The cDNA hybridized to two mRNAs (3.8 and 4.5 kb) found in the epidermis during the ecdysteroid rises for the embryonic, larval, and pupal molts. Culture of fourth instar larval epidermis with 4 microM 20-hydroxyecdysone (2 micrograms/ml 20HE) caused the appearance of MHR3 mRNA within 3 hr and maximal expression by 6 hr; after 12 hr continuous exposure to 20HE, the mRNA level declined. The 4.5-kb mRNA appeared first, both were present in equal amounts by 12 hr, and by 20 hr the predominant transcript was 3.8 kb. Similar 20HE-induced expression was seen in epidermis explanted 1 day after the onset of wandering, although with a slower time course. The induction was largely independent of protein synthesis, but the subsequent decline required protein synthesis as is typical of the "early" puffs in Drosophila. Continuous exposure to 20HE was necessary for MHR3 expression; in its absence, the mRNA declined with a half-life of 2 hr. Thus, MHR3 is an ecdysteroid-inducible DNA binding protein that likely is a transcription factor involved in the cascade of gene activation and inactivation caused by ecdysteroids during the insect molt.

Developmental profiles of epidermal mRNAs during the pupal-adult molt of Tenebrio molitor and isolation of a cDNA clone encoding an adult cuticular protein: effects of a juvenile hormone analogue

Changes in translatable mRNAs from the wing epidermis of the Coleoptera Tenebrio molitor have been investigated during metamorphosis by analysis of in vitro translated products. Striking differences between the patterns obtained from mRNAs extracted during pupal and adult cuticle secretion indicated that a drastic change in gene expression occurs during the pupal-adult transition. In addition to these stage-specific modifications, the mRNA patterns changed within each cuticular synthesis program (pupal or adult), especially at ecdysis. After tritiated leucine incorporation, some of the major radiolabeled cuticular proteins showed similar changes suggesting that the sequential appearance of mRNAs corresponds to sequential deposition of cuticular proteins. In supernumerary pupae obtained after juvenile hormone analogue (JHA) application on newly ecdysed pupae, translatable mRNA were very similar to those of pharate pupae. The JHA seemed, therefore, to prevent the expression of the adult program. By immunoblotting in vitro translated products with a monoclonal antibody recognizing an adult-specific cuticular protein, the developmental profile of the corresponding mRNA was studied. This mRNA was detected in anterior wing epidermis during the first 80 hr of the pharate adult stage. Using the same antibody, a cDNA clone was isolated from epidermal mRNA. The hybrid selected mRNA coded for only one protein with an apparent MW of 22 kDa which was, furthermore, recognized by the antibody. The Northern blot analysis performed with the clone confirmed the Western blot analysis of the in vitro translation products. JHA application at the beginning of the pupal-adult reprograming prevented the appearance of this mRNA; however, this transcript was present during the following molting cycle. This reversibility of the JHA action was confirmed by immunogold labeling of the cuticles formed in treated animals.

Hormonal regulation of epidermal metamorphosis in vitro: control of expression of a larval-specific cuticle gene

Fourth (penultimate) instar larval epidermis of the tobacco hornworm, Manduca sexta, was used to develop an in vitro culture system to study the hormonal control of metamorphosis at both the cellular and the molecular level. Immediate exposure to 4 x 10(-6) M 20-hydroxyecdysone (20-HE) for more than 8 hr, followed by hormone-free medium for 24 hr, caused the formation of a new larval cuticle. By contrast, incubation in hormone-free medium for more than 24 hr prior to exposure to 20-HE allowed pupal cuticle synthesis. The cessation of expression of the larval-specific cuticular gene LCP-14 occurred rapidly in response to 20-HE during the larval molt in vitro (half-life: ca. 6 hr), even in the presence of 3 x 10(-8) M JH I. This suppression by 20-HE was prevented by cycloheximide, indicating that 20-HE does not act directly on this gene. Incubation with alpha-amanitin showed that the half-life of LCP-14 was more than 10 hr. Thus, 20-HE must both suppress gene transcription and destabilize the mRNA. LCP-14 mRNA subsequently reappeared 24 hr after exposure to hormone-free medium, indicating that suppression was temporary. By contrast, when JH and its effects were absent after preincubation in hormone-free medium for 48 hr, 20-HE caused permanent suppression of LCP-14 mRNA, since the mRNA did not reappear after removal of 20-HE. Exposure of Day 2 fifth instar larval epidermis to 3 x 10(-7) M 20-HE, which causes pupal commitment in the absence of JH I, also permanently suppressed LCP-14 gene expression.

Ecdysteroid binding sites localized by autoradiography in the central nervous system of precommitment fifth-stadium Manduca sexta larvae

Brains and subesophageal ganglia from day 3.5 fifth stadium larvae of Manduca sexta were incubated in vitro with 4 nM tritiated ponasterone A, a 20-hydroxyecdysone analog, to determine whether uptake and specific binding of ecdysteroids occur at a cellular level. These tissues, which were taken just prior to the commitment peak in the hemolymph-ecdysteroid titer, showed saturable uptake of 3H-ponasterone A after 40-60 min of incubation. Uptake was blocked by the addition of 400 nM unlabelled ponasterone A, or of 500 nM or 1000 nM 20-hydroxyecdysone. RH 5849, a synthetic 20-hydroxyecdysone agonist with a long half-life, for which ecdysteroid receptors have low affinity, also reduced ponasterone A uptake at a concentration of 10 microM. Autoradiographs of 4 microns sections of brains revealed distinct nuclear concentrations of silver grains over cell populations in the pars intercerebralis, pars lateralis, and ventral tritocerebrum. Nuclear labelling was also found in many small cells around the mushroom bodies and the neuropil, and between the inner and outer larval optic lobes. Nuclear labelling of cells in the subesophageal ganglion was observed in the fronto-medial and lateral regions, in small cells around the neuropil, and caudally in a few large neurons. In addition to cells with nuclear labelling, both brains and ganglia at this development stage contained cells with exclusively cytoplasmic or both nuclear and cytoplasmic labelling. None of these apparent binding sites were observed in the competition experiments, suggesting that the binding is specific.

The urea-soluble low molecular weight cuticle proteins from the different developmental stages of Dacus oleae

The cuticle proteins of the insect Dacus oleae have been isolated by extraction with a solution of 7 M urea. The affinity properties of cuticle proteins, isolated from the third instar larvae (L3DCPs 1-7), to chitin have been studied. Purified cuticle antigens were polymerized by glutaraldehyde and used for raising antibodies. The developmental appearance of the cuticle proteins has been studied by two-dimensional electrophoresis.

Heat sensitivity and protein synthesis during heat-shock in the tobacco hornworm, Manduca sexta

Fifth instar larvae of the tobacco hornworm, Manduca sexta, tolerate 1-h exposures to temperatures as high as 42 degrees C. Above 42 degrees C, survival declines rapidly to 18% at 44 degrees C and 0% at 48 degrees C. As in other insects, the heat-shock response of Manduca sexta involves the induction of synthesis of heat-shock proteins very similar in size to the Drosophila heat-shock proteins (84, 73, 71, 27, 25, 23, and 22 kd). In the epidermis, heat-shock protein synthesis peaks at 42 degrees C, correlating with the heat sensitivity of both the tissue itself and the intact larva. Some heat-shock proteins have different isoelectric forms depending on tissue. Also, the heat-shock proteins are synthesized over a wider range of temperatures in the imaginal discs and the fat body as compared to the epidermis. In contrast to dipteran insects, Manduca sexta does not exhibit a strong repression of non-heat-shock protein synthesis under tolerable conditions.

Expression and hormonal control of a new larval cuticular multigene family at the onset of metamorphosis of the tobacco hornworm

The pattern of cuticular protein synthesis by the epidermis of the tobacco hornworm larva changes during the final day of feeding, leading to an alteration in cuticular structure and a stiffening of the cuticle. We have isolated a small multigene family which codes for at least three of the new cuticular proteins made at this time. The five genes which were isolated from this family map to two different genomic regions. Sequencing shows that one of the genes is 1.9 kb and consists of three exons coding for a 12.2-kDa acidic (pI = 5.26) protein that is predominantly hydrophilic. The deduced amino acid sequence shows regions of similarity to proteins from flexible lepidopteran cuticles and from Drosophila larval and pupal cuticles, but not to proteins found in highly sclerotized cuticles. This gene family is first expressed late on the penultimate day (Day 2) of feeding in the final larval instar and ceases expression 2 days later when metamorphosis begins. In situ hybridization shows that this gene family is expressed in all the epidermal cells of Day 3 larvae except the bristle cells and those at the muscle attachment site. Expression can be induced in Day 1 epidermis by exposure to 50 ng/ml 20-hydroxyecdysone in vitro, but only if juvenile hormone is absent. Its developmental expression, tissue specificity, and hormonal regulation strongly suggest that this multigene family is involved in the structural changes that occur in the larval cuticle just prior to the onset of metamorphosis.

Programmed cell death: dying cells synthesize a co-ordinated, unique set of proteins in two different episodes of cell death

Intersegmental muscles of the tobacco hornworm, Manduca sexta, degenerate promptly after the ecdysis of the moth. Protein content of the growing, static, and degenerating muscle was evaluated by two-dimensional electrophoresis; RNA was isolated from the muscle and translated, and the translation products likewise analyzed by two-dimensional electrophoresis. Growing and static muscles synthesize predominantly myofibrillar proteins, and small cytosolic proteins constitute a vanishingly small proportion of the proteins identified even by silver staining. When the muscle begins to degenerate, a large number of smaller proteins is seen on the gels. Many of these are apparently fragments of the myofibrillar proteins, but over 30 can be recognized as new translation products. Most of the translation products are found in two regions, one ranging from 20 to 40 kDa and with a pI of 6.5-6.9; and the other approx. 50-70 kDa and pI 5.8-6.2. The pattern is identical in two separate instances of degeneration.

Regulation of expression of arylphorin and female-specific protein mRNAs in the tobacco hornworm, Manduca sexta

Two non-cross-hybridizing cDNA clones were isolated from a lambda gt11 cDNA library prepared from Day 2 fifth instar female fat body of Manduca sexta and shown by hybrid selection to code respectively for the two storage proteins arylphorin and female-specific protein (FSP). Analysis of the developmental expression of arylphorin showed its presence during the feeding phases of the penultimate (fourth) and final (fifth) larval instars and its absence during the molt. Abdominal ligation of larvae followed by infusion of Grace's medium showed that this amino acid-rich medium was able to maintain arylphorin expression in fourth instar larvae, but not continued high expression in fifth instar larvae. This nutrient medium however was sufficient to allow initiation of expression in newly ecdysed fifth larval abdomens. Infusion of 5 micrograms 20-hydroxyecdysone (20HE) caused a significant reduction of arylphorin RNA in ligated fourth larval abdomens, whereas 50 micrograms was required in Day 2 fifth larval abdomens to suppress this RNA. Thus, both the lack of incoming nutrients and the rising titer of ecdysteroid contribute to the loss of arylphorin mRNA at the molts and at wandering. By contrast, FSP mRNA was first detected in females on Day 2 of the fifth instar, but not in males until wandering, and then was present throughout the prepupal period. In females allatectomy caused the precocious appearance of FSP mRNA which was prevented by application of 10 micrograms methoprene, a juvenile hormone analog. Expression of FSP mRNA in males however appeared to be independent of hormonal milieu.

Synthesis of two storage proteins during larval development of the tobacco hornworm, Manduca sexta

Studies of synthesis and accumulation of the two storage proteins arylphorin and female-specific protein (FSP) during the final two larval instars of the tobacco hornworm showed both stage and temporal specificity. Arylphorin was present in both stages, but its synthesis ceased during the molt, during starvation, and at the wandering stage, and then resumed about 24 hr after the onset of feeding. During the larval molt about 25% of injected iodinated arylphorin was incorporated into the newly forming fifth instar cuticle. The cessation of arylphorin synthesis was mimicked by exposure of the fat body to 1 microgram/ml 20-hydroxyecdysone (20HE) in complete Grace's medium or to dilutions of Grace's medium greater than 50%. Lower concentrations of 20HE were ineffective, indicating that the cessation of synthesis in vivo was likely due to a combination of lack of excess nutrients and the hormonal milieu. The female-specific protein was not synthesized until the final larval instar, appearing first in females on Day 2 and later in males at the time of wandering, with synthesis continuing throughout the prepupal period. In vitro studies showed that this protein was synthesized as a 620-kDa protein, and then during secretion a 730-kDa immunoreactive form also appeared. Synthesis of FSP was inhibited by exposure of Day 2 fat body to 1 microgram/ml 20HE for 24 hr. Ligation followed by 20HE infusion showed that the disappearance of FSP from the hemolymph during the prepupal period was controlled by the rising ecdysteroid titer.

Granular phenoloxidase involved in cuticular melanization in the tobacco hornworm: regulation of its synthesis in the epidermis by juvenile hormone

The granular phenoloxidase (PO) that is responsible for cuticular melanization in Manduca sexta larva was purified and an antibody was prepared. This granular PO was found to consist of four isozymes of 90 kDa with isoelectric points ranging from 5.7 to 5.85. The enzyme was immunologically and electrophoretically distinct from the cuticular wound PO, a second cuticular PO common to all larval cuticle, and the hemolymph PO. Both [14C]mannose and [14C]sialic acid were incorporated into the granular PO, showing that this granular PO was a glycoprotein whose sugar moiety was a complex oligosaccharide. When no juvenile hormone (JH) was present at the head capsule slippage (HCS) stage, the epidermis began synthesizing PO 6 hr later. This epidermal synthesis was maximal 12 hr after HCS at which time the PO appeared in the cuticle, and then synthesis declined. When synthesis ceased about 23 hr after HCS, no further incorporation into the cuticle was observed. As melanization proceeded, immunologically detectable cuticular PO decreased. Application of 0.1 microgram JH I at the time of HCS inhibited synthesis of PO by the epidermis and thus prevented melanization. JH application after PO synthesis had begun (8 hr after HCS) prevented its subsequent synthesis, causing partial melanization. Thus, the absence of JH is necessary during the period of epidermal synthesis of the granular PO to allow complete melanization.

Stage and segment specificity of the secretory cell of the dermal glands of the tobacco hornworm, Manduca sexta

The pair of epidermally derived Verson's glands on each segment of the tobacco hornworm, Manduca sexta, secretes at ecdysis proteinaceous products which coat the epicuticle. These proteins are produced by a single secretory cell which displays both stage- and segment-specificity during development. Three major 12-kDa polypeptides are synthesized at the larval molts, while higher molecular weight (14-93 kDa) polypeptides are produced at the pupal molt. In the pupa, but not in the larva, there are three segment-specific protein patterns, each involving both qualitative and quantitative differences: (1) thoracic (T) segments 1 and 2; (2) T3 and abdominal (A) segment 1; (3) A2-A8. Larval-specific proteins were found to be synthesized in low amounts throughout the penultimate fourth instar, with enhanced synthesis occurring during the molt, coincident with the molting surge of ecdysteroids. Synthesis of the major pupal products commenced about the time of wandering, with enhanced synthesis occurring throughout prepupal development, coincident with the prepupal surge in ecdysteroids. The onset of synthesis of the major pupal products differed, both within and between segments. Culture of fifth instar Day 2 glands in vitro showed that this synthesis depended on 20-hydroxyecdysone. The differential regulation within and between segments observed in vivo was also seen in vitro.

Structure and expression of a Manduca sexta larval cuticle gene homologous to Drosophila cuticle genes

A genomic clone was isolated from the tobacco hornworm, Manduca sexta, by virtue of its similarity to a Drosophila larval cuticle gene. RNA analysis shows that this clone, B311, is expressed at times appropriate for a larval cuticle gene. Hybrid-selection experiments using B311 DNA show that it encodes a 14 x 10(3) Mr protein, LCP-14, which is precipitated by an antiserum to Manduca larval cuticle. We have sequenced both genomic and cDNA clones for the LCP-14 gene. A conceptual translation of the cDNA sequence shows that the LCP-14 protein is similar not only to another Manduca cuticle protein, but also to Drosophila, Sarcophaga and Hyalophora cecropia cuticle proteins. Since these proteins are found in flexible cuticle and have similar sequences, we conclude they are encoded by homologous genes.

Developmental regulation of the larval hemolymph protein genes in Galleria mellonella

The role of juvenile hormone (JH) and 20-hydroxyecdysone (20-HE) in the stage-specific expression of the larval hemolymph protein (LHP) genes, Lhp82 and Lhp76, was investigated in the waxmoth, Galleria mellonella, larvae. Northern blot and dot hybridization analyses of total RNA in larvae that were undergoing an extralarval molt, induced either by cold shock or by application of JH to day-0 last instar larvae, showed that the last instar-specific Lhp82 transcripts were not present during this molt cycle. Lhp76 transcripts were, however, present transiently. During the course of an extralarval molt induced by JH in day-3 larvae both the transcripts were present but they were relatively less abundant than in the controls. JH had no effect on the relative abundance of the Lhp transcripts when applied to ligated day-3 or older larvae. By contrast, application of 20-HE either to intact or prothorax-ligated larvae of different developmental stages as well as to fat body in vitro resulted in a rapid decrease in the relative abundance of the Lhp transcripts. The natural decrease in the Lhp transcript levels that occurs in wandering and spinning last instar larvae was blocked in ligated larvae, probably due to deprivation of the source of the endogenous ecdysteroids. These observations suggest that ecdysteroids serve as the natural cue to turn off the Lhp genes at each molt and that JH blocks activation of only the last instar-specific Lhp82 gene.

Developmental expression of three genes for larval cuticular proteins of the tobacco hornworm, Manduca sexta

Three cDNA clones coding for the 12.8, 13.3, and 14.6 kDa larval cuticular proteins of the tobacco hornworm, Manduca sexta, were isolated and characterized. Hybridization to abdominal epidermal RNA from different stages showed that the genes for the 12.8 and 13.3 kDa proteins were expressed only during larval life. By contrast, the gene for the 14.6 kDa protein was expressed throughout the segment during the feeding, growing larval stages, then only in the flexible intersegmental regions during the deposition of endocuticle in the pharate pupa and adult. Quantitative RNA dot blot hybridizations showed that the RNA for each protein disappeared during the larval molt when the ecdysteroid titer was high, then reappeared during the preecdysial deposition of endocuticle. All disappeared when the epidermis became pupally committed at the onset of wandering. Exposure of the fourth instar epidermis to 20-hydroxyecdysone (20HE) in vitro under conditions that lead to the formation of a new larval cuticle by 48 hr caused the disappearance of these RNAs by 18 hr. Exposure of Day 2 fifth instar epidermis to 20HE in vitro caused a depression of these RNAs which in the case of the RNAs coding for the 12.8 and 13.3 kDa proteins was partially prevented by simultaneous exposure to methoprene, a juvenile hormone (JH) mimic. By contrast, the RNA for the 14.6 kDa protein was suppressed by exposure to methoprene alone. Thus, each of these larval cuticular genes is turned off by high ecdysteroid; the presence or absence of JH determines whether or not this suppression is permanent in some or all cells.

Development of the prepupal Verson's gland of the tobacco hornworm, Manduca sexta, and its hormonal control

The segmentally arranged Verson's glands are epidermal derivatives comprised of three cells: the duct, saccule, and secretory cells. The development of these glands was followed through the 5th instar and larval-pupal transition of Manduca sexta. The glands are relatively small during the feeding stage, begin to grow at wandering, and undergo about a 50-fold increase in size during the prepupal period. The increase in size is due mainly to the hypertrophy of the secretory cell which synthesizes a heterogeneous set of proteinaceous secretory products. Three prominent 11 to 12 kiloDalton (kD) polypeptides are made by the pharate fifth larval gland, whereas the pupal gland produces polypeptides ranging from 14 to 75 kD with a major complex at 30 to 34 kD. The secretory product is poured out onto the surface of the new cuticle at the time of ecdysis and contains all of the major proteins detected in extracts of the whole gland. The accumulation of secretory products by the gland occurs during the prepupal peak of ecdysteroid and is blocked if this rise is prevented by abdominal isolation. Infusion of 30 micrograms 20-hydroxyecdysone (20-HE) into such isolated abdomens caused synthesis of the pupal products. Treatment with the juvenile hormone mimic, methoprene, during the fifth instar showed that the commitment of the glands to produce the pupal proteins is independent of and occurs before the overlying epidermis becomes committed to make pupal cuticle.

Procuticle proteins and chitin-like material in the inner epicuticle of the Drosophila pupal cuticle

The inner (protein) epicuticle of the pupal cuticle of Drosophila is shown to contain at least two hydrophobic proteins (19 and 21 kD) that are also present in the outer procuticle lamellae. An N-acetylglucosamine-containing carbohydrate is also present in the inner epicuticle. This represents the first attempt to characterize the non-lipid components of an insect epicuticle.