Factors influencing the developmental capacity of Galleria larval epidermis

The nature of the cuticle secreted by integument from a day-1 penultimate instar larval Galleria when cultured in vivo in the abdomen of a last instar larva varied with the age of the host. When placed in a day-5 last instar larva, the implanted integument secreted a pupal cuticle at the time the host metamorphosed and became a pupa. However, when placed in a day-7 last instar larva the implant, from the same stage donor, secreted a larval cuticle at the time the host pupated. Experimental studies involving implantation of the integument for a 24 hr period, into various developmental stages of normal and ligated last instar larvae, pupae, and pharate adults, prior to placing it in a day-7 last instar larva suggest that a non-hormonal factor present in day-4 and -5 last instar larvae is important to initiate pupal syntheses.     

Reprogramming and DNA Synthesis in Galleria mellonella Larval Epidermal Cells

Epidermal cells from ligated day-3 last instar larvae of Galleria mellonella secrete a larval cuticle if exposed to ecdysone immediately following ligation; whereas, they deposit a pupal cuticle if exposed to ecdysone three to four days after ligation. During the period of reprogramming the genome in the diploid cells of the wax moth larvae no DNA synthesis occurs. This is direct proof that DNA synthesis is not required for reprogramming in the epidermis of Galleria during larval-pupal transformation.     

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.     

Control of pupal commitment in the imaginal disks of Precis coenia (Lepidoptera: Nymphalidae)

When final (5th) instar larvae of Precis coenia were treated with the juvenile hormone analog (JHA) methoprene, they underwent a supernumerary larval molt, except for certain regions of their imaginal disks, which deposited a normal pupal cuticle. Evidently those regions had already become irreversibly committed to pupal development at the time JHA was applied. By applying JHA at successively later times in the instar, the progression of pupal commitment could be studied. Pupal commitment in the proboscis, antenna, eye, leg and wing imaginal disks occurred in disk-specific patterns. In each imaginal disk there were distinct initiation sites where pupal commitment began during the first few hours of the final larval instar, and from which commitment spread across the remainder of the disk over a 2- to 3-day period. The initiation sites were not always located in homologous regions of the various disks. As a rule, pupal commitment also spread from imaginal disk tissue to surrounding epidermal tissue. The regions of pupal commitment in all disks except those of the wings, coincided with the regions of growth of the disk. Only portions of the disk that had undergone cell division and growth underwent pupal commitment. Shortening the growth period did not prevent pupal commitment in the wing imaginal disk, indicating that, in this disk at least, a normal number of cell divisions was not crucial in reprogramming of disk cells for pupal cuticle synthesis. The apparent growth spurt of imaginal disks that occurs during the last part of the final larval instar is merely the final stage of normal and constant exponential growth. Juvenile hormone (JH) and ecdysteroids appeared to play little role in the regulation of normal imaginal disk growth. Instead, growth of the disks may be under intrinsic control. Interestingly, even though endogenous fluctuation in JH titers do not affect imaginal disk growth, exogenous JHA proved able to inhibit both pupal commitment, cell movement, and growth of the disks during the last larval instar. This function of JH could be important under certain adverse conditions, such as when metamorphosis is delayed in favor of a supernumerary larval molt.     

Some aspects of activity regulation of Galleria mellonella PTTH cells

Using the Galleria prothoracicotropic bioassay, five small neurosecretory cells occurring in each dorsolateral part of protocerebrum of Galleria mellonella brain were identified as prothoracicotropic hormone (PTTH) cells. It was found that the critical period for the release of PTTH from a brain implanted in neck-ligated larva lasts up to the third day after implantation. The content of paraldehyde-fuchsin positive neurosecretory material (NSM) in PTTH cells was determined during the penultimate and last larval instar, during pupal instar, and in starved or poststarvation fed or space-deprived last instar larvae. Two peaks of NSM in PTTH cells were found in the penultimate instar (in freshly molted, and 76-h-old larvae), four peaks in the last instar larvae (in freshly molted, and in 67-, 132-, and 174-h-old larvae), and one peak in the pupal instar (in 56-76-h-old pupae). It was also observed that upon starvation NSM accumulated in PTTH cells, while after 3 h of poststarvation feeding it was released. In permanent space-deprived last instar larvae no NSM occurred in PTTH cells. In all investigated larval instars a rapid release of NSM from PTTH cells was found a few hours after molt associated with the beginning of the feeding period. The significance of the NSM content in PTTH cells is discussed in relation to ecdysteroid titer.     

Apolysis without ecdysis in larval development of a strepsipteran, Elenchus tenuicornis (Kirby)

Previous uncertainty concerning the number of larval stages in a strepsipteran ( Elenchus tenuicornis ) was resolved by transmission and scanning electron microscope observations. The first larval instar (triungulinid) is free-living: after entering the host (a delphacid) it undergoes a normal ecdysis. The resulting second instar larva undergoes two further apolyses without ecdysis. In the male, the cuticle of the fourth instar larva tans to form the puparium, while the female becomes sexually mature without a further moult after extrusion of the cephalothorax through the host cuticle. The discarded exuviae of the triungulinid remain in the host abdomen; subsequent larval staging is made possible by the retention of the exuviae ensheathing the larva as each apolysis is accomplished.     

Temporal programming of epidermal cell protein synthesis during the larval-pupal transformation ofManduca sexta

Summary During the final larval instar the epidermis of the tobacco hornworm,Manduca sexta, synthesizes the larval cuticular proteins and the pigment insecticyanin. Then at the onset of metamorphosis the cells first become pupally-committed, then later produce the pupal cuticle. The changes in the pattern of epidermal protein synthesis during this period were followed by incubating the integument in vitro with either³H-leucine or³⁵S-methionine, then analyzing the proteins by 2-dimensional gel electrophoresis. Precipitation by larval and pupal cuticular antisera and by insecticyanin antibody identified these proteins. Three distinct changes in epidermal protein synthesis were noted: 1) Stage-specific proteins, some of which are larval cuticular proteins, appear just before and during the change of commitment on day 3. (2) By late the following day (wandering stage), synthesis of these and many other proteins including all the identified larval cuticular proteins and insecticyanin was undetectable. Several noncuticular proteins were transiently synthesized by this pupally committed cell during wandering and sometimes the following day. (3) During the production of pupal cuticle a new set of pupal-specific cuticular proteins as well as some common cuticular proteins (precipitated by both antisera) were synthesized. Some of the latter were also synthesized during the period between pupal commitment and pupal cuticle deposition.In spite of an apparent absence of methionine in both larval and pupal cuticle, many cuticular proteins incorporated³⁵S-methionine. Thus they may be synthesized as proproteins.Insecticyanin was shown to have two forms differing in isoelectric point, the cellular form being more acidic than the hemolymph form. Synthesis of the cellular form ceased before that of the hemolymph form.     

X-ray investigation of gas bubble formation, and water loss in tsetse fly pupae

ABSTRACT. Using a microfocal X-ray apparatus, a gas bubble was detected within the puparium of Glossina morsitans. The bubble appeared between 6 and 15 h after pupariation and was associated with one of the longitudinal tracheal trunks of the third instar larva. The bubble grew and achieved maximum size approximately 96 h after pupariation. It then disappeared at the time of eversion of the pupal appendages. There was a close correlation between bubble size and the weight of water lost since the time of pupariation. At the time of eversion of the pupal appendages the gas bubble apparently passed out through the longitudinal tracheal trunk and posterior spiracle to occupy the space between larval (puparial) and pupal cuticle. It is suggested that the bubble plays a vital role in the separation of these cuticular layers and that to this end water loss from the puparium is essential.     

The cuticle proteins of Drosophila melanogaster: stage specificity

Five stage-specific cuticles are produced during the development of Drosophila. Urea-soluble proteins were extracted from each developmental stage and compared by gel electrophoresis. Proteins from first and second instar cuticle are identical except for minor differences in two proteins. Each subsequent stage, third instar, pupa, and adult, has a unique set of cuticle proteins. Qualitative changes within stages are seen in proteins from third instar and adult cuticle. Third instar cuticle proteins can be divided into “early” [proteins 2a, 3, 4, 5, 7, and 8] and “late” [proteins 2 and 1] groups. Adult cuticle proteins change in relative amounts during pharate adult development and change mobility at eclosion. The lower abdominal pupal cuticle lacks a protein found in the pupal cuticle covering the head and thorax. Cuticle proteins from each stage are immunologically related. Nonetheless, electrophoretic variants of three larval proteins do not affect any major changes in the electrophoretic mobility of proteins from other stages. We propose that each stage (except first and second instar) has proteins encoded by discrete genes.     

Protein crosslinking by transglutaminase controls cuticle morphogenesis in Drosophila

Transglutaminase (TG) plays important and diverse roles in mammals, such as blood coagulation and formation of the skin barrier, by catalyzing protein crosslinking. In invertebrates, TG is known to be involved in immobilization of invading pathogens at sites of injury. Here we demonstrate that Drosophila TG is an important enzyme for cuticle morphogenesis. Although TG activity was undetectable before the second instar larval stage, it dramatically increased in the third instar larval stage. RNA interference (RNAi) of the TG gene caused a pupal semi-lethal phenotype and abnormal morphology. Furthermore, TG-RNAi flies showed a significantly shorter life span than their counterparts, and approximately 90% of flies died within 30 days after eclosion. Stage-specific TG-RNAi before the third instar larval stage resulted in cuticle abnormality, but the TG-RNAi after the late pupal stage did not, indicating that TG plays a key role at or before the early pupal stage. Immediately following eclosion, acid-extractable protein from wild-type wings was nearly all converted to non-extractable protein due to wing maturation, whereas several proteins remained acid-extractable in the mature wings of TG-RNAi flies. We identified four proteins--two cuticular chitin-binding proteins, larval serum protein 2, and a putative C-type lectin-as TG substrates. RNAi of their corresponding genes caused a lethal phenotype or cuticle abnormality. Our results indicate that TG-dependent protein crosslinking in Drosophila plays a key role in cuticle morphogenesis and sclerotization.     

Cell cycle changes during growth and differentiation of imaginal leg discs in Drosophila melanogaster

The relative DNA content of Drosophila melanogaster imaginal leg disc nuclei during larval growth and pupal and adult differentiation was measured by microspectrophotometry. During the larval proliferative phase there were twice as many nuclei in the 4C class as nuclei in the 2C class. At the end of the third larval instar, the proportion of nuclei with a 4C DNA value increased. By 3 hr after pupariation, during pupal cuticle secretion, 90% of the nuclei were in this class. After pupal apolysis which occurs at 12 hr after pupariation, the 4C to 2C ratio was reversed. The increase in the proportion of nuclei with a 2C value was observed until 24 hr after pupariation when 90% of the nuclei were in this class. We propose that most cells divide at least once between pupal and adult differentiation. All of these changes in the cell cycle were correlated temporally with changes in the ecdysteroid titers that occur during these periods.     

Replacement of midgut epithelium in the greater wax moth,Galleria mellonela,during larval-pupal moult

The epithelium of larval midgut of the greater wax moth, Galleria mellonela, was replaced during the larval-pupal moult. The development of this moth was tentatively divided into 11 stages, from the full-grown larva of last instar to the 4-day-old pupa. The midgut at each stage was observed for (1) overall structure, (2) the position of goblet cells, and (3) the appearance of the yellow body. Light microscopy revealed that cell death in the midgut began in a cocoon-spinning larva (stage II), when pigments in the stemmata started to migrate. Before drastic remodeling started to occur, cytoplasmic projections in the goblet cavities were transformed. The larval midgut changed markedly at stage III, when the pigments left the stemmata. The epithelium of the larval midgut dropped as a whole into the lumen, transforming into the yellow body. Simultaneously, a pupal midgut epithelium developed. Electron microscopy of the columnar cells of a stage III larva showed that microvilli and mitochondria looked normal even though the nucleus with condensed heterochromatin resembled an apoptotic nucleus of vertebrate and higher plant cells. Caspase-3-like protease activity was restricted to the larval midgut and increased in parallel with the formation of the yellow body. The results indicate that the replacement of the larval midgut is facilitated by a typical apoptotic process.     

The callajoppine parasitoids of sphingids in Central America (Hymenoptera: Ichneumonidae)

Abstract. An illustrated key is presented to the three genera of the ichneumonine subtribe Callajoppina that are known to occur in Central America. A new species, Tricyphus respinozai , is described from north-western Costa Rica and brief notes are given about its biology as a larval/pupal parasitoid of Manduca dilucida Hiibner (Lepidoptera: Sphingidae). The cephalic capsules of the final instar larva and a preultimate instar larva of T.respinozai are described.     

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.     

Progress of developmental programme during the last larval instar of Bombyx mori: Relationships with food intake,ecdysteroids and juvenile hormone

The progress of developmental programme in the epidermal cells of last instar larvae of Bombyx mori was determined by ecdysteroid injections in normal and in JH-treated larvae. To clarify the importance of food intake in the control of development, starved animals were also used.The instar begins with a period during which the larval programme is expressed: this occurs in the presence of 20-hydroxyecdysone. Epidermal cells can thereafter secrete pupal cuticle after ecdysteroid injection although the larval programme is normally still present. During the last period only pupal characters can be expressed either in normal or in 20-hydroxyecdysone-injected larvae.These different developmental phases are not correlated with obligatory and facultative feeding periods.Transition from the first to the second phases is correlated with the absence of JH effects on pupal genes. JH applications during the second period, however, prevent the expression of pupal characters after 20-hydroxyecdysone injection. Thus, during this period, the pupal programme is not stabilized. Cellular reprogramming itself occurs at the onset of the last developmental period and is probably under the control of ecdysteroids.     

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.     

Two gene families clustered in a small region of the Drosophila genome

Three Drosophila genes that are clustered within 8 X 10(3) bases of DNA at the chromosomal region 44D have been identified and mapped, and the gene cluster entirely sequenced. The three genes are 55 to 60% homologous in DNA sequence. One gene contains an intron in its 5'-proximal protein coding sequence while the other two have none at this position; similarly, another gene has an intron in its 3'-proximal protein coding sequence which is not found in the other genes. All three genes are abundantly expressed together in Drosophila first, second, and early third instar larval stages and in adults, but they are not abundantly expressed in either embryonic, late third instar larval, or pupal stages. This gene family lies 11 X 10(3) bases away from another cluster containing four Drosophila larval cuticle protein genes plus a pseudogene. The cuticle genes are all abundantly expressed throughout third instar larval development. Thus, at least seven protein-coding genes and one pseudogene lie within 27 X 10(3) bases of DNA. Moreover, two small gene families can lie adjacent on a chromosome and exhibit different patterns of developmental regulation, even though individual genes within each clustered family are co-ordinately expressed.     

The rôle of ecdysone in pupation of Manduca sexta

Slow infusions of β-ecdysone are more effective in eliciting a normal physiological response than are discrete injections of the hormone. Infusion of β-ecdysone into final instar larvae in the presence of juvenile hormone (JH) induces apolysis and the deposition of a normal larval cuticle. In the absence of JH larvae display the prodromal symptoms of pupation (exposure of the heart, purging of the gut, etc.) in response to a β-ecdysone infusion. The occurrence of certain covert physiological events that accompany the exposure of the heart are evidently necessary to prepare a larva for pupation. An infusion of β-ecdysone can induce apolysis and pupal cuticle deposition only after the prodromal signs of pupation have become evident. Of the two pulses of ecdysone that normally precede pupation in Manduca, the first is apparently responsible for the genetic switchover from larval to pupal development whereas the second one triggers apolysis and the subsequent events that lead to pupation. Results obtained from infusion experiments in which the dose and exposure time were varied independently are consistent with the idea that ecdysone has to be present for a certain minimum time above a threshold concentration to induce a physiological response. The requisite exposure time is apparently not dose-dependent.     

Purification,properties, and titer of a hemolymph trophic factor in larvae and pupae of Manduca sexta

Purification of a hemolymph protein (hemolymph trophic factor, or HTF) from last instar larvae of Manduca sexta was achieved using Sephadex G15-120 gel filtration and DEAE anion exchange chromatography. Homogeneity was visualized using SDS gel electrophoresis and ampholytic chromatofocusing. HTF was estimated to be a tetrameric protein with a molecular weight of 286 K and a Stokes' radius of 55.3 × 10⁻⁸ cm by agarose bead gel filtration; chromatofocusing suggests an isoionic point > 10. Polyclonal antibodies to HTF were prepared in rabbits and an ELISA was developed. The ELISA was used to titer HTF during the last larval instar and day 1 and 14 of the pupal stage and estimates a maximum of 1.5 mg/ml larval hemolymph on day 6 with a smaller larval peak of 0.75 mg/ml at day 3 and titers of 0.70 and 0.35 mg/ml on the 2 pupal days, respectively. ELISA of aqueous extracts of larval fat body, epidermis, and cuticle demonstrate that HTF comprises nearly a third of the soluble fat body protein and is a lesser component of epidermis and cuticle. The physiological role of HTF has not yet been determined.