Soldier determination in Pheidole bicarinata: Effect of methoprene on caste and size within castes

Topical application of methoprene to final-instar larvae of the ant Pheidole bicarinata can induce soldier development. Soldier induction takes place if methoprene levels are above a soldier-determining threshold during a critical period of juvenile hormone-sensitivity that occurs during about days 4–6 of the final instar. Furthermore, the amount of exogenous methoprene applied affects the timing of metamorphosis and the adult size in both the minor worker and soldier castes. When larvae that receive methoprene treatment become minor workers these are always larger than acetone-treated controls. In larvae that become soldiers, growth and timing of metamorphosis vary with the dose of methoprene, but in a more complex way. A high dose of methoprene produces a metamorphic delay and large soldiers. However, the lowest effective dose for soldier induction produces early metamorphosis and small adults. On the basis of these results, we have expanded our model of a mechanism by which juvenile hormone could control determination of worker castes in Pheidole bicarinata.     

Soldier determination in Pheidole bicarinata: Inhibition by adult soldiers

In the ant Pheidole bicarinata, adult soldiers suppress the induction of soldier developments in larvae that have been treated with methoprene, as well as in acetone-treated controls. Induction of soldier development is inhibited in methoprene-treated larvae when the adult soldiers are present as nurses, when they are present in the colony but minor workers serve as nurses, and when they are held in a minor worker-permeable cage to prevent them from contacting larvae. Suppression of soldier determination can be overridden by high doses of methoprene applied during the juvenile hormone-sensitive period for soldier determination. The degree of suppression increases with increasing contact between larvae and adult soldiers. The most likely mechanism of inhibition is a contact soldier pheromone. On the basis of our results, we expand our model of soldier determination to accommodate the fact that the threshold titre of juvenile hormone necessary to induce soldier development changes in the presence of soldiers. A threshold that is sensitive to the presence of adult soldiers provides a mechanism whereby the worker caste ratio in colonies can be regulated.     

Wing disc development during caste differentiation in the ant Pheidole megacephala (Hymenoptera: Formicidae)

The genus Pheidole has three distinct castes in females: queen, major, and minor workers. It has been believed that the larvae of major workers have prominent mesothoracic wing discs, although the minor worker larvae lack them. Here we conducted histological examinations of wing discs during larval development in P. megacephala. We show that all three castes have mesothoracic wing discs, at least in their early stage of the final larval instar, and that the wings degenerate differently in the dimorphic worker castes. The minute wing discs of minor workers neither grow nor metamorphose but disappear during the prepupal stage. On the contrary, the wing discs of major workers evaginate at the onset of the prepupal stage but subsequently degenerate by apoptotic cell death. This apoptotic wing degeneration in the prepupal stage was contradistinguished from wing degeneration in some lepidopteran insects, in which apoptosis occurs in the pupal wing buds. Our results suggest that each worker caste shows a different degeneration process to express the wingless character and that apoptotic degeneration has been adopted in association with the evolution of worker dimorphism.     

A comparison of protein synthesis in imaginal wing discs of wild-type and vestigial of Drosophila melanogaster

In vitro incorporation of labelled amino acids into TCA insoluble protein in the imaginal wing discs of vg mutant and wild-type Drosophila melanogaster is compared and correlated with the extent of cellular degeneration during development. (1) With 96–100-hr-old larvae, wing discs isolated from vg mutant incorporate radiolabelled amino acids at a higher rate than wild-type discs, although cellular degeneration is more extensive in vg discs than wild-type discs. This may reflect the larger size of the vg discs since they have more protein than the wild-type discs. (2) The vg discs of 105–110-hr-old larvae have a lower rate of incorporation than the wild-type disc, although both types of discs have the same protein content. This may be due to the presence of more degenerating cells in the vg discs. (3) The rate of incorporation in vg discs of 115–118-hr-old larvae is lower than that of wild-type discs; the vg discs have less protein but more degenerative cells than the wild-type discs. The rates of protein degradation are similar in both discs. Electrophoretic comparison reveals a general reduction in protein synthesis in vg discs as compared with wild-type discs.     

Soldiers are differentiated from male larval stages in incipient colonies of <Emphasis Type="Italic">Nasutitermes takasagoensis</Emphasis> (Isoptera: Termitidae)

In phylogenetically ancestral taxa of termites (the so-called lower termites), at least one soldier emerges and is maintained longitudinally in each incipient colony. However, in apical taxa (the so-called higher termites), the developmental pathway and regulation of soldiers in incipient colonies currently remain unknown. We therefore examined soldier and worker development in incipient colonies of higher termites (Nasutitermes takasagoensis Shiraki). Developmental stages and castes were successfully discriminated by head width in incipient colonies 4 months after colony foundation. Furthermore, differences were observed in the number of bristles on antennae between first- and second-instar larvae. In N. takasagoensis, there was more than one soldier in each incipient colony 4 months after its foundation. Presoldiers in the incipient colonies were differentiated from an earlier instar (male second-instar larvae), whereas, in mature colonies, they were differentiated from male third instars (= minor workers). The developmental period of the former (7 days) was markedly shorter than that of the latter (14 days). All female second-instar larvae molted into workers. The developmental processes shown here are useful for obtaining a clearer understanding of the mechanisms of soldier/worker differentiation in higher termites.     

Growth and patterning are evolutionarily dissociated in the vestigial wing discs of workers of the red imported fire ant, Solenopsis invicta

Over the last decade, it has become clear that organismal form is largely determined by developmental and evolutionary changes in the growth and pattern formation of tissues. Yet, there is little known about how these two integrated processes respond to environmental cues or how they evolve relative to one another. Here, we present the discovery of vestigial wing imaginal discs in worker larvae of the red imported fire ant, Solenopsis invicta. These vestigial wing discs are present in all worker larvae, which is uncommon for a species with a large worker size distribution. Furthermore, the growth trajectory of these vestigial discs is distinct from all of the ant species examined to date because they grow at a rate slower than the leg discs. We predicted that the growth trajectory of the vestigial wing discs would be mirrored by evolutionary changes in their patterning. We tested this prediction by examining the expression of three patterning genes, extradenticle, ultrabithorax, and engrailed, known to underlie the wing polyphenism in ants. Surprisingly, the expression patterns of these three genes in the vestigial wing discs was the same as those found in ant species with different worker size distributions and wing disc growth than fire ants. We conclude that growth and patterning are evolutionarily dissociated in the vestigial wing discs of S. invicta because patterning in these discs is conserved, whereas their growth trajectories are not. The evolutionary dissociation of growth and patterning may be an important feature of gene networks that underlie polyphenic traits.     

Isolation and characterization of temperature-sensitivelethal(2)giant larva alleles

Summary In this paper we present an analysis of the behavior ofl(2)gl ^tsimaginal wing discs during culture in adult hosts. Thel(2)gl ^tslarvae reared at 29° C contain two types of wing discs, those that are morphologically normal and those that are abnormal. When discs of both types are cultured in adult hosts at 29° C, the restrictive temperature, they give rise to transplantable neoplastic tissue. However, when the 29° C reared discs are cultured at 15° C, the permissive temperature, the morphologically normal discs maintain their morphology, but the morphologically abnormal discs give rise to neoplasms. Thel(2)gl ^tslarvae reared at 15° C contain only morphologically normal discs. When these discs are cultured in adult hosts at 29° C they give rise to neoplasms, however if the discs are cultured at 15° C they maintain their normal morphology. These results demonstrate: (1) that all wing imaginal discs obtained from 29° C rearedl(2)gl ^tslarvae are competent to undergo neoplastic development, (2) the morphologically abnormal discs obtained from the 29° C rearedl(2)gl ^tslarvae are committed to neoplastic development, (3) the neoplastic development of the morphologically normal discs is temperature dependent, (4) once the neoplastic development of thel(2)gl ^tsdiscs has been initiated the process is not readily reversible. In addition, the ability ofl(2)gl ^tswing discs to perform epimorphic regulation was tested by amputating morphologically normal permissively rearedl(2)gl ^tswing discs and culturing both fragiments at the permissive temperature. Fragments of control wild-type discs maintained their morphology during culture at the permissive temperature. However, both fragments of txel(2)gl ^tsdiscs became neoplastic. This result is discussed with respect to a possible role for thel(2)gl ⁺function in epimorphic regulation and with respect to the phenomena of tumor promotion in vertebrates.     

High Laccase2 expression is likely involved in the formation of specific cuticular structures during soldier differentiation of the termite Reticulitermes speratus

Termite soldiers are morphologically specialized for colony defense. Analysis of the mechanisms of soldier differentiation is important for understanding the establishment of termite societies. Soldiers differentiate from workers through a presoldier stage and have well-sclerotized and pigmented cuticles. These characteristics are important for nest defense and are likely to be caused by soldier-specific mechanisms of cuticular tanning. The molecular mechanisms leading to cuticular tanning have not been elucidated. Laccase2 (Lac2) plays important roles in this process in insects, and we hypothesized that Lac2 expression may be involved in soldier-specific cuticular tanning. We observed inner and outer head cuticle changes and compared the Lac2 expression patterns among three molts (worker–worker, worker–presoldier and presoldier–soldier) in the termite Reticulitermes speratus. Quantitative analyses of head cuticle colors showed that the color properties changed more conspicuously in presoldier–soldier molts than in the other two molts. Histological observations showed that the exocuticles of soldier heads were substantially thicker than those of worker and presoldier heads, underwent tanning before or just after ecdysis, and were pigmented at earlier time points than other molts. Finally, markedly higher Lac2 expression levels were observed just before and after ecdysis only in the presoldier–soldier molt. These results suggest that specific cuticular formation occurs in the exocuticles during soldier differentiation, and that the high level of Lac2 expression during the presoldier–soldier molt is related to soldier-specific cuticular tanning. We speculate that evolution of the regulatory mechanisms of Lac2 expression were important for the acquisition of soldier-specific cuticles.     

The coordination of growth among Drosophila organs in response to localized growth-perturbation

The developmental mechanisms by which growth is coordinated among developing organs are largely unknown and yet are essential to generate a correctly proportioned adult. In particular, such coordinating mechanisms must be able to accommodate perturbations in the growth of individual organs caused by environmental or developmental stress. By autonomously slowing the growth of the developing wing discs within Drosophila larvae, we show that growing organs are able to signal localized growth perturbation to the other organs in the body and slow their growth also. Growth rate is so tightly coordinated among organs that they all show approximately the same reduction in growth rate as the developing wings, thereby maintaining their correct size relationship relative to one another throughout development. Further, we show that the systemic growth effects of localized growth-perturbation are mediated by ecdysone. Application of ecdysone to larvae with growth-perturbed wing discs rescues the growth rate of other organs in the body, indicating that ecdysone is limiting for their growth, and disrupts the coordination of their growth with growth of the wing discs. Collectively our data demonstrate the existence of a novel growth-coordinating mechanism in Drosophila that synchronizes growth among organs in response to localized growth perturbation.     

Anchor negatively regulates BMP signalling to control Drosophila wing development

G protein-coupled receptors play particularly important roles in many organisms. The novel Drosophila gene anchor is an orthologue of vertebrate GPR155. However, the roles of anchor in molecular functions and biological processes, especially in wing development, remain unknown. Knockdown of anchor resulted in an increased wing size and additional and thickened veins. These abnormal wing phenotypes were similar to those observed in BMP signalling gain-of-function experiments. We observed that the BMP signalling indicator p-Mad was significantly increased in wing discs in which anchor RNAi was induced in larvae and accumulated abnormally in intervein regions in pupae. Furthermore, the expression of target genes of the BMP signalling pathway was examined using a lacZ reporter, and the results indicated that omb and sal were substantially increased in anchor-knockdown wing discs. An investigation of genetic interactions between Anchor and the BMP signalling pathway revealed that the thickened and ectopic vein tissues were rescued by knocking down BMP levels. These results suggested that Anchor functions to negatively regulate BMP signalling during wing development and vein formation.     

Correlations between spatiotemporal changes in gene expression and apoptosis underlie wing polyphenism in the ant Pheidole morrisi

Wing polyphenism, which is the ability of a single genome to produce winged and wingless castes in a colony in response to environmental cues, evolved just once and is a universal feature of ants. The gene network underlying wing polyphenism, however, is conserved in the winged castes of different ant species, but is interrupted at different points in the network in the wingless castes of these species. We previously constructed a mathematical model, which predicts that a key gene brinker (brk) mediates the development and evolution of these different "interruption points" in wingless castes of different ant species. According to this model, brk is upregulated throughout the vestigial wing discs of wingless ant castes to reduce growth and induce apoptosis. Here, we tested these predictions by examining the expression of brk, as well as three other genes up- and downstream of brk-decapentaplegic (dpp), spalt (sal), and engrailed (en)-in the winged reproductive and wingless soldier castes in the ant Pheidole morrisi. We show that expression of these genes is conserved in the wing disc of winged castes. Surprisingly, however, we found that brk expression is absent throughout development of the vestigial soldier forewing disc. This absence is correlated with abnormal growth of the soldier forewing disc as revealed by En expression and morphometric analyses. We also discovered that dpp and sal expression change dynamically during the transition from larval-to-prepupal development, and is spatiotemporally correlated with the induction of apoptosis in soldier forewing disc. Our results suggest that, contrary to our predictions, brk may not be a key gene in the network for suppressing wings in soldiers, and its absence may function to disrupt the normal growth of the soldier forewing disc. Furthermore, the dynamic changes in network interruptions we discovered may be important for the induction of apoptosis, and may be a general feature of gene networks that underlie polyphenism.     

Pupal commitment and its hormonal control in wing imaginal discs

The timing of pupal commitment of the forewing imaginal discs of the silkworm, Bombyx mori, was determined by a transplantation assay using fourth instar larvae. The wing discs were not pupally committed at the time of ecdysis to the fifth instar. Pupal commitment began shortly after the ecdysis and was completed in 14 h. When the discs of newly molted larvae (0-h discs) were cultured in medium containing no hormone, they were pupally committed in 26 h. In vitro exposure of 0-h discs to 20-hydroxyecdysone accelerated the progression of pupal commitment. Methoprene, a juvenile hormone analog (JHA), did not suppress the change in commitment in vitro at physiological concentrations. Thus the wing discs at the time of the molt have lost their sensitivity to JH, and 20E is not a prerequisite for completion of pupal commitment. These results suggest that the change in commitment in the forewing discs may begin before the last larval molt.     

Mitosis in neoplastic and hyperplastic imaginal discs ofDrosophila

Homozygosity for recessive mutations inDrosophila tumour suppressor genes likelethal giant larvae (Igl), lethal giant discs (Igd) orfat (ft) induce uncontrolled cell proliferations in the imaginal discs of the mutant larvae. Imaginal discs of larvae mutant forIgl tumour suppressor gene display neoplastic growths while those mutant forIgd orfat display hyperplastic growths. Results presented in this study reveal that mutant wing imaginal discs with neoplastic or hyperplastic overgrowths display high mitotic activity primarily during the extended period of larval life when their wild-type siblings have already pupariated. Both these categories of overgrowths show overall stability of the karyotypes and only low frequency of aneuploidy. The hyperplastic imaginal discs ofIgd orft mutant larvae displayed normal chromosome condensation. In contrast, the neoplastic imaginal discs ofIgl mutants showed high frequency of mitotic cells with undercondensed chromosomes. In this respect the neoplastic discs resemble malignant neuroblastomas of theIgl larvae which also display undercondensed chromosomes. These results thus suggest an indirect role of the cytoskeletal protein encoded byIgl tumour suppressor gene in aspects of normal chromosome condensation during mitosis.     

The appearance of dopa decarboxylase activity in imaginal discs of Sarcophaga bullata, undergoing development in vitro

During the postembryonic development of Sarcophaga bullata, two large peaks of dopa decarboxylase activity were observed. These were associated with the sclerotization (hardening) of the puparium and the adult cuticle, respectively. A small peak of activity 5.5–6.5 days after pupariation was possibly associated with the sclerotization of the prothoracic spiracles.A premature increase in enzyme activity was observed in young, third-instar larvae injected with 20 μg of β-ecdysone. However, the advantage of studying the effect of the hormone on enzyme activity in vitro led to an attempt to induce² dopa decarboxylase in cultured wing discs.In the presence of β-ecdysone, wing discs underwent evagination and a substantial increase in dopa decarboxylase activity was observed in these discs. The enzyme activity began to appear after the rupture of the peripodial membrane and reached a maximum about the time disc evagination ceased. We suggest that this enzyme activity was responsible for the slight sclerotization of a fine cuticle secreted by the discs. The cultured imaginal discs underwent changes that are very similar to those which occur in intact animals. Therefore, this system appears promising for further studies on the role in differentiation of the hormonal control of enzyme activity.     

Colony demographics of rare soldier-polymorphic worker caste systems in <Emphasis Type="Italic">Pheidole</Emphasis> ants (Hymenoptera,Formicidae)

Nearly all species in the ant genus Pheidole have dimorphic workers, with distinct small minors and larger soldiers. The size range of both castes is typically narrow. Just seven described species are soldier-polymorphic, with a broad soldier size range. Here, we characterize worker caste allocation and demography in the soldier-polymorphic P. obtusospinosa, P. rhea, and P. tepicana, and the dimorphic P. spadonia for comparison. The head allometry of soldiers in soldier-polymorphic species is strongly positive and that of dimorphic species is negative. Among soldier-polymorphic species, the soldier castes differ from each other in the degree of positive allometry. In addition, they differ in the number of size modes: P. obtusospinosa and P. rhea have two and P. tepicana has one. During colony ontogeny, P. obtusospinosa first has one mode and develops the second mode much later, while P. rhea produces multiple modes throughout. We also characterize worker caste systems based on the biomass allocation. For all three soldier-polymorphic species, the majority of soldiers are small soldiers. Pheidole obtusospinosa and P. rhea allocate roughly equal biomass to the two soldier classes, while P. tepicana allocates little to supersoldiers based on both biomass and caste ratio. These findings illustrate the interplay among caste ratios, biomass allocation, size frequency distributions, and allometry in the evolution of different worker caste systems. We conclude that soldier-polymorphic species may have evolved convergently in response to broad-scale factors, but differences among them suggest selection pressures in small-scale environments have been different.     

Patterns of protein synthesis in the imaginal discs of Drosophila melanogaster: a comparison between different discs and stages

High-resolution two dimensional gel electrophoresis has been used to study the patterns of protein synthesis in imaginal discs of Drosophila melanogaster. In this paper we first compare the patterns of protein synthesis in wing, haltere, leg 1, leg 2, leg 3 and eye antenna imaginal discs of late third instar larvae. We have detected only quantitative changes: differences in 17 proteins among the different imaginal discs. In addition, we have analysed the variations in pattern of proteins in the wing disc of the last larval stage and early pupae as well as in wing discs cultured in vivo for 6 days. Variations in these patterns affect more than 20% of the proteins and involve both qualitative and quantitative changes. Some of the changes may correspond to protein phosphorylation. Correlations of these changes between discs and through development are also discussed. Correspondence to: F. Santaren     

Effect of the wingless (wg1) mutation on wing and haltere development in Drosophila melanogaster

Genetic and developmental studies of wingless (wg¹), a new second chromosome recessive mutation in Drosophila melanogaster, have shown that it affects not only wing and haltere development (giving rise to wingless and/or halterless flies), but also results in various abnormalities of the mesothorax. The larvae destined to develop into wingless and/or halterless flies possessed underdeveloped mesothoracic and/or metathoracic imaginal discs.     

Expression of phenotypes in a temperature-sensitive allele of the apterous mutation in Drosophila melanogaster

A temperature-sensitive allele of the apterous (ap) locus of Drosophila melanogaster has been used to examine the phenotypes produced by this mutation, which include wing, mesonotal, and haltere deficiencies, precocious adult death, and nonvitellogenic oocyte development. When raised at 15°C, homozygous ap^ts78j adults have nearly wild-type wing morphology except for patches of missing triple-row bristles and posterior wing margin deficiencies. With the exception of two missing bristles, the dorsal mesonotum and the haltere appear as wild-type. Increasing deficiency of structures derived from the wing and haltere imaginal discs results from increasing culture temperature, and at 29°C, the wing blade, many dorsal mesonotal bristles, and the haltere are absent. The temperature-sensitive period in development for these deficient phenotypes extends from late-second to mid-third instar. Despite extensive deficiencies seen after ap^ts78j larvae are heat-pulsed at 29°C, no duplication of the notal structures is evident, a common response of other mutants having extensive wing deficiencies. When raised at 29 or 25°C, ap^ts78j adults are short-lived, and females show nonvitellogenic oocyte development. At 22°C, however, adults are long-lived, and females are vitellogenic and lay fertile eggs. A sharp temperature-sensitive period for both phenotypes is located during the first 24 hr of pupal development. The application of a juvenile hormone mimic, ZR-515, restored vitellogenesis to ap^ts78j females raised at 25°C but was unable to rescue them from precocious death.     

The wings ofBombyx mori develop from larval discs exhibiting an early differentiated state: a preliminary report

Lepidopteran insects present a complex organization of appendages which develop by various mechanisms. In the mulberry silkworm,Bombyx mori a pair of meso- and meta-thoracic discs located on either side in the larvae gives rise to the corresponding fore- and hind-wings of the adult. These discs do not experience massive cell rearrangements during metamorphosis and display the adult wing vein pattern. We have analysed wing development inB. mori by two approaches, viz., expression of patterning genes in larval wing discs, and regulatory capacities of larval discs following explantation or perturbation. Expression of Nubbin is seen all over the presumptive wing blade domains unlike inDrosophila, where it is confined to the hinge and the wing pouch. Excision of meso- and meta-thoracic discs during the larval stages resulted in emergence of adult moths lacking the corresponding wings without any loss of thoracic tissues suggesting independent origin of wing and thoracic primordia. The expression of wingless and distal-less along the dorsal/ventral margin in wing discs correlated well with their expression profile in adultDrosophila wings. Partially excised wing discs did not showin situ regeneration or duplication suggesting their early differentiation. The presence of adult wing vein patterns discernible in larval wing discs and the patterns of marker gene expression as well as the inability of these discs to regulate growth suggested that wing differentiation is achieved early inB. mori. The timings of morphogenetic events are different and the wing discs behave like presumptive wing buds opening out as wing blades inB. mori unlike evagination of only the pouch region as wing blades seen inDrosophila.