Changes in ploidy level of epidermal cells during last larval instar of the tobacco hornworm, Manduca sexta

The relative DNA content of Manduca sexta abdominal epidermal nuclei during the final larval instar was measured by cytophotometry of whole-mount preparations of the epidermis. In the middle intrasegmental region, epidermal cells showed a ploidy level of 4C to 32C on the day of ecdysis. During the subsequent period of feeding, the proportion of higher ploidy cells, such as 16C and 32C, increased. This situation remained until the day of apolysis preceding pupal cuticle formation when mitoses reduced the cells to 2C, 4C, 8C and 16C, except for the pupal pock-mark cells, which increased to 32C or 64C. Metaphase cells showed various ploidy levels, correlated with the size of their mitotic figures. By contrast, in the anterior and posterior margin of a segment where no mitoses occurred, the cells continued to increase in ploidy throughout the instar.     

Development of polyploidy of scale-building cells in the wings of Manduca sexta

The developing wings of butterflies and moths are composed of two epithelial monolayers. Each epithelial sheet is made up of two kinds of cells, diploid cells that make up the epidermal surface and body of the wing, and large polyploid cells that become the scale-building cells whose cytoplasmic projections develop into the scales that will cover the adult wing and bear the pigment pattern. We studied the development of polyploidization of the scale-building cells during the pupal stage of the tobacco hornworm moth, Manduca sexta. The endomitotic divisions of the presumptive scale-building cells and the mitotic divisions of the diploid epithelial cells begin on day 3 of the pupal stage and continue until day 7. We show that scales of different colors and positions on the wing differ in size, and that the size of the scale is proportional to the ploidy of the scale-building cell. Scale-building cells are arranged in irregular rows and within each row there is an alternation of ploidy levels, with the lower ploidy cells giving rise to the underscales and the higher ploidy cells giving rise to the cover scales that carry the color pattern. Along the wing there is a proximo-distal decreasing gradient of average ploidy and scale size. Scale-building cells of high ploidy are surrounded by fewer epidermal cells than those of low ploidy. This inverse relationship is known as Henke's compensation principle, which posits that the number of endomitoses of a pre-polyploid cell and the number of mitotic divisions of its diploid daughter cell add up to a constant. We show that the inverse relationship fits the predictions of the compensation principle and does not fit constraints imposed by packing density, and we discuss mechanisms that could give rise to the inverse relationship.     

The precocious commitment of wing Anlagen in Tenebrio molitor revealed by the addition of 20-hydroxyecdysone

An injection of 20-hydroxyecdysone (10 mug per animal) 6-13 days after the moult of the last larval instar of Tenebrio molitor induces the development of prothetelic larvae and larval-pupal intermediates. The state of larval-pupal switchover, or commitment, is only disclosed at the time of injection of the moulting hormone. Prothetelic A and B larvae, with small and medium sized wing Anlagen, undergo another larval or pupal instar. Prothetelic C larvae with bigger Anlagen are unable to moult, but the adult programme is expressed. Ecdysed larval-pupal intermediates give more or less perfect adults, while unecdysed mealworms, imprisoned in their larval cuticle, also expressed the adult programme. The commitment of Tenebrio is not a global switchover because a significant asynchronisation is noted between the development of organs considered. Animal crowding induces a delay in the appearance of wing Anlagen.     

Hormonal regulation and patterning of the broad-complex in the epidermis and wing discs of the tobacco hornworm, Manduca sexta

Expression of Manduca Broad-Complex (BR-C) mRNA in the larval epidermis is under the dual control of ecdysone and juvenile hormone (JH). Immunocytochemistry with antibodies that recognize the core, Z2, and Z4 domains of Manduca BR-C proteins showed that BR-C appearance not only temporally correlates with pupal commitment of the epidermis on day 3 of the fifth (final) larval instar, but also occurs in a strict spatial pattern within the abdominal segment similar to that seen for the loss of sensitivity to JH. Levels of Z2 and Z4 BR-C proteins shift with Z2 predominating at pupal commitment and Z4 dominant during early pupal cuticle synthesis. Both induction of BR-C mRNA in the epidermis by 20-hydroxyecdysone (20E) and its suppression by JH were shown to be independent of new protein synthesis. For suppression JH must be present during the initial exposure to 20E. When JH was given 6 h after 20E, suppression was only seen in those regions that had not yet expressed BR-C. In the wing discs BR-C was first detected earlier 1.5 days after ecdysis, coincident with the pupal commitment of the wing. Our findings suggest that BR-C expression is one of the first molecular events underlying pupal commitment of both epidermis and wing discs.     

20-Hydroxyecdysone accelerates the flow of cells into the G1 phase and the S phase in a male accessory gland of the mealworm pupa (Tenebrio molitor)

The cells of the bean-shaped accessory glands of mealworms proliferate through the first 7 days of the 9-day pupal stage. Immediately after larval-pupal ecdysis, 25-27% of the cells were in the G1 phase, 60-65% were in the G2 phase, and the balance were in S phase. Over the first 4 days of normal development, the S fraction gradually increased, to reach its highest level in the mid-pupa at the time of the major ecdysteroid peak (Delbecque et al., 1978). Thereafter, the S fraction declined until over 95% of the cells had accumulated in G2 on Day 8. When 0-day pupal glands were explanted into Landureau's S-20 medium for 6 days, the G1 fraction remained fairly constant (25-30%) while S and the G2 fractions fluctuated. On the first day in vitro, the G2 fraction declined and the S fraction rose. On the second day in basal media, the S fraction fell and G2 rose correspondingly until 70% of the cells reached G2 when cycling stopped on the third day. With addition of 20-hydroxyecdysone to 0-day cultures, the S fraction increased quite sharply. It remained large for all 6 days of the experiment in the continuing presence of hormone. A 1-day pulse of hormone produced a transient increase in S. We blocked cell cycling with hydroxyurea in a stathmokinetic experiment and showed that 20-hydroxyecdysone accelerated the flow of cells from the G2 phase to the G1 phase by 2.5-fold. An increase in the G1 fraction was detected within 10 hr of hormone administration and the effect was dose-dependent with an ED50 of 5 X 10(-7) M for 20-hydroxyecdysone. We conclude that 20-hydroxyecdysone acts at a control point in the G2 phase. Incubation of the glands with 20-hydroxyecdysone for only 30-60 min followed by washout stimulated the flow from G2 to G1 and the effect persisted after transfer of the tissues to hormone-free media. Dose-dependent stimulation also occurred with ponasterone A (ED50 3 X 10(-9] but not with cholesterol.     

Correlations between epidermal cell structure and endogenous hormone titers during the fifth larval instar of the tobacco hornworm, Manduca sexta

Epidermal cell morphology and cuticle production in Manduca sexta are directly influenced by both ecdysterone and juvenile hormone. Up to day 6 of the last larval instar, post-molt endocuticle is continuously deposited even though cells undergo a partial and temporary separation from the overlying cuticle at the time when a small ecdysteroid peak is detected (approximately day 3.5). At about days 6--7 when another, larger ecdysteroid peak is present, apolysis occurs accompanied by the appearance of edcysial droplets. Following apolysis, layers of pupal cuticle are deposited. Increased quantities of rough endoplasmic reticulum characterize the epidermis at times of peak endocuticle deposition (day 3, larval cuticle; day 9, pupal cuticle). Dense pigment inclusions are found in epidermis from the day of ecdysis to the last larval instar until they are eliminated 5 days later. These dense bodies migrate from cell apex to base in the absence of juvenile hormone (or in the presence of a negligible amount of juvenile hormone) and probably contain insecticyanin.     

The cell cycle of epidermal cells during reprogramming in the pupa of Galleria

The epidermal cell cycle of the pupal mesonotum of Galleria was investigated by the determination of mitotic indices, [³H]thymidine incorporation and flow-cytophotometric analysis during the first 48 h after pupation.Immediately after the pupal ecdysis nearly all epidermal cells are arrested in G2. Thereafter only a few mitoses occur, leading to a slow increase in the number of G1 nuclei. With the onset of a mitotic wave at a pupal age of 21 h this increase becomes more rapid. On day 2, the cell population reaches a plateau in the number of G1 (resp. G2) cells, reflecting a steady state between mitotic activity and DNA synthesis.A comparison of these cell cycle changes with known data of the time course of reprogramming and ecdysteroid titre leads to the conclusion that there is no causal relationship between DNA synthesis and cellular determination in the sense of a quantal cell cycle, and that DNA synthesis can precede the definite rise in ecdysteroid titre.     

Reciprocal transplantation of wing discs between a wing deficient mutant (fl) and wild type of the silkworm, Bombyx mori

The wingless mutant flügellos ( fl ) of the silkworm lacks all four wings. Although wing discs of the fl seem to develop normally until the fourth larval instar, wing morphogenesis stops after the fourth larval ecdysis, probably caused by aberrant expression of an unidentified factor, referred to as fl . To characterize factor fl , the wing discs dissected from the wild-type (WT) and fl larvae were transplanted into other larvae and developmental changes of the discs were examined. When the wing disc from a WT larva was transplanted into another WT larva and allowed to grow until emergence, a small wing appeared that was covered with scales. Thus, the transplanted wing discs can develop autonomously, form scales and evert from adult skin. The WT wing discs transplanted into the fl larvae also developed at a high rate. However, the fl wing discs transplanted into the WT larvae did not develop during the larval to pupal developmental stages. These data suggest that the fl gene product (factor fl) works in the wing disc cells during wing morphogenesis. Its function cannot be complemented by hemolymph in the WT larva. It is also implied that the level of humoral factors and hormones required for wing morphogenesis are normally maintained in the fl larva.     

Changes in the activity of dopa quinone imine conversion factor during the development of Bombyx mori

The activity of DOPA quinone imine conversion factor (QICF) in tissues at different developmental stages of the silkworm, Bombyx mori, was determined. QICF activity was detected in all developmental stages from egg to pupa although the activities, other than in fifth instar larvae, were quite low. Activity in whole larvae peaked one day before the onset of larval-pupal development and declined to a low level shortly before ecdysis. In whole pupae, maximal QICF activity was obtained 1 h after pupation. The activity in larval cuticles was elevated on the last day of the fourth instar and again between days 4 and 8 of the fifth instar, decreasing to very low levels before pupal ecdysis. QICF was detectable in pupal cuticles with most of the pupal activity found in homogenates of mid and hind guts. A major part of the total larval QICF activity was found in hemolymph. Activity in hemolymph varied in a different manner from that in cuticles, with markedly raised levels immediately before pupal ecdysis when the cuticular activity had declined. It is postulated that QICF in cuticles plays some role in wound healing and/or sclerotizatio,, while QICF in hemolymph participates in melanization in the humoral immune system.     

Programmed cell death in the wing of Orgyia leucostigma (Lepidoptera: Lymantriidae)

Programmed cell death is an integral and ubiquitous phenomenon of development that is responsible for the reduction of wing size in female moths of Orgyia leucostigma (Lymantriidae). Throughout larval and pupal life, cells of the wing epithelium proliferate and interact to form normal imaginal discs and pupal wings in both sexes. But at the onset of adult development, most cells in female O. leucostigma wings degenerate over a brief, 2-day period. Lysosomes and autophagic vacuoles appear in cells of the wing epithelium shortly after it retracts from the pupal cuticle. Hemocytes actively participate in removing the resulting cellular debris. By contrast, epithelial cells in wings of developing adult males of O. leucostigma do not undergo massive cell death. Wing epithelium of female pupae transferred to male pupal hosts behaves autonomously in this foreign environment. By pupation, cells of the female wing apparently are committed to self-destruct even in a male pupal environment. Normal interactions among epithelial cells within the plane of a wing monolayer as well as between the upper and lower monolayers of the wing are disrupted in female O. leucostigma by massive cell degeneration. Despite this disruption, the remaining cells of the wing contribute to the formation of a diminutive, but reasonably proportioned, adult wing with scales and veins.     

Characteristics of two genes encoding proteins with an ADAM-type metalloprotease domain, which are induced during the molting periods in Bombyx mori

By microarray analyses, we identified two genes (BmADAMTS-1 and BmADAMTS-like) encoding a protein, which are induced during the pupal ecdysis in the wing discs of Bombyx mori; these genes are homologous to ADAMTS family members (a disintegrin and metalloproteinase domain, with thrombospondin type-1 repeats). A complete metal-binding motif of the ADAM-type metalloprotease domain (HEXXHXXGXXHD) was contained in both amino acid sequences. However, thrombospondin type 1 (TSP-1) repeats were observed only in BmADAMTS-1. The BmADAMTS-1 gene was expressed in the hemocyte and midgut of the larvae at day 2 of wandering stage (W2), and strongly induced during the pupal ecdysis in the hemolymph. The BmADAMTS-like gene was expressed in the epithelial tissues of the larvae at W2, and had expression peaks slightly later than the BmADAMTS-1 gene. Our results indicate that BmADAMTS-1 and BmADAMTS-like may cleave the extracellular matrix (ECM) in the degenerating and remodeling tissues during the molting periods.     

The developmental expression of serotonin-immunoreactivity in the brain of the pupal honeybee

The biogenic amine serotonin is a neurotransmitter and modulator in both vertebrates and invertebrates. In the CNS of insects, serotonin is expressed by identifiable subsets of neurons. In this paper, we characterize the onset of expression in the brain and suboesophageal ganglion of the honeybee during pupal development. Several identified serotonin-immunoreactive neurons are present in the three neuromeres of the suboesophageal ganglion the dorsal protocerebrum, and the deutocerebrum at pupal ecdysis. Further immunoreactive neurons are incorporated into the developing pupal brain in two characteristic developmental phases. During the first phase, 5 days after pupal ecdysis, serotonin immunoreactivity is formed in the protocerebral central body, the lamina and lobula, and the deutocerebral antennal lobe. During the second phase, 2 days later, immunoreactivity appears in neurons of the protocerebral noduli of the central complex, the medulla, and the pedunculi and lobes of the mushroom bodies. Three novel serotonin-immunoreactive neurons that innervate the central complex and the mushroom bodies can be individually identified.     

Changes in ecdysone titre during pupal-adult development in the silkworm, Bombyx mori

Changes in the ecdysone titre of the silkworm, Bombyx mori, during pupal-adult development were estimated. The average value of the maximum titre, which was observed on the second day after pupal ecdysis, was about 0·8 μg equivalent of β-ecdysone/g of live weight in both sexes.

There is a distinct sexual dimorphism in the pattern of the ecdysone titre. The male exhibited a single sharp peak on the second day whereas the female showed the second peak on the fifth day. When the female was ovariectomized, the ‘female type’ ecdysone pattern was converted to the ‘male type’. In the female pharate adult 7 days after pupal ecdysis, ecdysone activity accumulated in the ovaries.

The relationship between the ecdysone titre and adult differentiation, especially during ovarian development, is discussed.     

Dynamics and metamorphosis of an identifiable peptidergic neuron in an insect

Eclosion hormone (EH) is a 7000 Da peptide that triggers ecdysis behavior in insects. In the moth, Manduca sexta, EH is found in two pairs of ventromedial (VM) cells in the brain which send their axons down the ventral nerve cord to a neurohemal site in the proctodeal nerve in the larva and pupa. During adult development, these cells send axon collaterals to the corpora cardiaca where they form a new release site used for adult eclosion. Studies of bioassayable peptide during the 5th larval instar and the larval-pupal transformation revealed that after depletion at ecdysis, the VM cells showed a transient increase in EH found in their cell bodies and axons. By contrast, their terminals in the proctodeal nerve showed a gradual accumulation of peptide followed by a release of over 90% of the stored material at pupal ecdysis. In situ hybridization analysis on whole mounts of the brains showed that the VM cells always contained EH mRNA with increased accumulation during the larval and pupal molting periods with a slight decline just before ecdysis. High levels of EH mRNA were found in brains of diapausing pupae. During the first two-thirds of adult development, mRNA accumulated to high levels, then slowly declined until ecdysis. EH mRNA levels up to 3 days after adult eclosion. At no time was EH mRNA found in the lateral neurosecretory cell cluster previously reported to produce EH for adult eclosion. 1994 John Wiley & Sons, Inc.     

Costs of insecticide resistance in Cydia pomonella (Lepidoptera: Tortricidae)

The obvious benefits associated with insecticide resistance for pest species may come at a cost to other life-history traits. In this study, we compared the larval and pupal developmental times, pupal mass wing surface area and wing fluctuating asymmetry (FA) in insecticide resistant and control strains of codling moth, Cydia pomonella (L.) (Lepidoptera: Tortricidae), collected from apple (Malus spp.) orchards in central Canada. Resistant strains had significantly longer larval developmental times and lower pupal masses compared with the susceptible strain. Although the forewings of resistant moths were smaller in resistant than control strain, no difference in wing FA was detected. Longer developmental times could increase exposure time to natural enemies, and reduced adult size could affect longevity and total reproductive output.     

Developmental Changes in the Bombyxin-and Insulin-like Immunoreactive Neurosecretory System in the Wax Moth, Galleria mellonella

Four medial neurosecretory cells (MNC) and 4 lateral neurosecretory cells (LNC) in each brain hemisphere, and one pair of cells in each thoracic ganglion (TG) of Galleria larva react with antibodies against bombyxin and insulin. Material secreted from the MNC and LNC is released mainly in the corpora allata, and that from the TG through the ventral median nerves. Intrinsic secretory cells of the corpora cardiaca (CC) also contain bombyxin-like, but not insulin-like material. The immunoreactivities all disappear during molts and reappear with resumption of feeding. In the MNC and TG they reappear for less than a day, but in cells of the CC immunoreactivity reappears for the whole feeding period. Before pupation, the LNC become temporarily immunopositive towards the end of feeding period, and the MNC and TG during the wandering period, i.e. at the time of prothoracic gland stimulation. Immunoreactivity disappears during the pupal molt. In pupae it is present in the 4 pairs of MNC and 1–2 pairs of LNC 12–48 hr after ecdysis, and in cells of the CC from 12 hr after ecdysis until the end of the pupal instar. In adult, immunoreactivity is restricted to 2 pairs of the LNC and to CC cells.     

Commencement of pupal commitment in late penultimate instar and its hormonal control in wing imaginal discs of the silkworm, Bombyx mori

Pupal commitment of the wing imaginal disc of the silkworm, Bombyx mori, is completed shortly after the final (fifth) larval ecdysis. Pupal commitment was induced by in vitro culture with 20-hydroxyecdysone (20E). Shortly after the head capsule slippage (HCS) that occurs approximately 24 h before the final larval ecdysis, the discs become competent to respond to 20E, indicating that the process of pupal commitment begins in the late penultimate (fourth) instar. The simultaneous presence of methoprene (JHA) with 20E suppressed the pupal commitment at 4 ng/ml for the discs at 12 h after HCS and at 240 ng/ml for the discs at the ecdysis. Thus, the discs rapidly lose their sensitivity to JH at the end of the fourth instar. Day 0 fourth wing discs were not pupally committed by 20E when freshly dissected discs were exposed to 20E. By contrast, exposure to 20E after a pre-culture in a hormone free medium induced the pupal commitment. In those discs, the effective JHA concentration to suppress the 20E effects was 0.1 ng/ml. The present data suggest that pupal commitment proceeds through two stages from a reversible state that begins at around HCS to an irreversible state early in the fifth instar. The loss of sensitivity to JH is the primary impetus to begin the process and 20E is the factor that drives the discs to enter the reversible state.     

Differentiation of insect sensory neurons in the absence of their normal synaptic targets.

Sensory neurons in the antenna of the moth, Manduca sexta, arise and differentiate during the 18 days of metamorphosis from pupa to adult, sending axons to the brain. To assess the trophic dependence of developing antennal neurons on their targets, we studied antennae from surgically debrained animals. If the brain is removed 1 to 45 hr after pupal ecdysis (before and during the period when antennal neurons arise by cell divisions), adult development can be triggered by injection of β-ecdysone; if the brain is removed 50 to 60 hr after pupal ecdysis (before antennal axons contact the brain), metamorphosis proceeds spontaneously. Neurons proliferate normally and differentiate extensively in the antennae of debrained animals. They acquire a characteristic size and shape, elaborate axons and dendrites, migrate to appropriate positions in the sensilla, accumulate components of a neurotransmitter system (acetylcholine, choline acetyltransferase, and acetylcholinesterase), and generate electrical responses to olfactory and mechanical stimuli. Antennal sensory neurons thus differ from a variety of vertebrate neurons, which fail to mature when deprived of their synaptic targets.