Massive excretion of calcium oxalate from late prepupal salivary glands of Drosophila melanogaster demonstrates active nephridial‐like anion transport

The Drosophila salivary glands (SGs) were well known for the puffing patterns of their polytene chromosomes and so became a tissue of choice to study sequential gene activation by the steroid hormone ecdysone. One well‐documented function of these glands is to produce a secretory glue, which is released during pupariation to fix the freshly formed puparia to the substrate. Over the past two decades SGs have been used to address specific aspects of developmentally‐regulated programmed cell death (PCD) as it was thought that they are doomed for histolysis and after pupariation are just awaiting their fate. More recently, however, we have shown that for the first 3–4 h after pupariation SGs undergo tremendous endocytosis and vacuolation followed by vacuole neutralization and membrane consolidation. Furthermore, from 8 to 10 h after puparium formation (APF) SGs display massive apocrine secretion of a diverse set of cellular proteins. Here, we show that during the period from 11 to 12 h APF, the prepupal glands are very active in calcium oxalate (CaOx) extrusion that resembles renal or nephridial excretory activity. We provide genetic evidence that Prestin, a Drosophila homologue of the mammalian electrogenic anion exchange carrier SLC26A5, is responsible for the instantaneous production of CaOx by the late prepupal SGs. Its positive regulation by the protein kinases encoded by fray and wnk lead to increased production of CaOx. The formation of CaOx appears to be dependent on the cooperation between Prestin and the vATPase complex as treatment with bafilomycin A₁ or concanamycin A abolishes the production of detectable CaOx. These data demonstrate that prepupal SGs remain fully viable, physiologically active and engaged in various cellular activities at least until early pupal period, that is, until moments prior to the execution of PCD.     

Respiratory metabolism of salivary glands during the late larval and prepupal development of Drosophila melanogaster

During the late larval period, the salivary glands (SG) of Drosophila show a cascade of cytological changes associated with exocytosis and the expectoration of the proteinaceous glue that is used to affix the pupariating larva to a substrate. After puparium formation (APF), SG undergo extensive cytoplasmic vacuolation due to endocytosis, vacuole consolidation and massive apocrine secretion. Here we investigated possible correlations between cytological changes, the puffing pattern in polytene chromosomes and respiratory metabolism of the SG. The carefully staged SG were explanted into small amounts (1 or 2 μl) of tissue culture medium. The respiratory metabolism of single or up to 3 pairs of glands was evaluated by recording the rate of O₂ consumption using a scanning microrespirographic technique sensitive to subnanoliter volumes of the respiratory O₂ or CO₂. The recordings were carried out at times between 8 h before pupariation (BPF), until 16 h APF, at which point the SG completely disintegrate. At the early wandering larval stage (8 h BPF), the glands consume 2 nl of O₂/gland/min (=2500 μl O₂/g/h). This relatively high metabolic rate decreases down to 1.2–1.3 nl of O₂ during the endogenous peak in ecdysteroid concentration that culminates around pupariation. The metabolic decline coincides with the exocytosis of the proteinaceous glue. During and shortly after puparium formation, which is accompanied cytologically by intense vacuolation, O₂ consumption in the SG temporarily increases to 1.6 nl O₂/gland/min. After this time, the metabolic rate of the SG decreases downward steadily until 16 h APF, when the glands disintegrate and cease to consume oxygen. The SG we analyzed from Drosophila larvae were composed of 134 intrinsic cells, with the average volume of one lobe being 37 nl. Therefore, a single SG cell of the wandering larva (with O₂ consumption of 2 nl/gland/min), consumes each about 16 pl of O₂/cell/min. A simultaneous analysis of the rate of protein and RNA synthesis in the SG shows a course similar to that found in respiratory metabolism.     

Comparative characteristics of the puffing pattern and the endocrine system in an oregon laboratory stock and in l(2)gl Drosophila melanogaster mutants differing in the time of their death

This study shows that homozygotes for different alleles of the lethal mutant, l(2)gl, differing in the time of death also vary in the state of their endocrine system and the puffing patterns of their salivary gland chromosomes. Homozygotes which die at the larval stage have underdeveloped prothoracic glands and normal corpora allata (CA); in those dying at the prepupal stage both the prothoracic glands and the CA are equally underdeveloped. — All the early third instar larval puffs (96–110 h., PS 1–2) develop in homozygotes; however, the reduction of some early larval puffs, normally occurring before pupariation or at puparium formation, is delayed. Some puffs are more developed than normal. — The differences in puffing patterns chiefly concerned puffs which normally appear 4–5 h before puparium formation and at puparium formation. In homozygotes lethal as larvae some of the puffs normally active at this time did not develop. However, along with some of the late larval puffs, there appeared many puffs characteristic of prepupae. — In homozygotes lethal as prepupae only the time and sequence of puff appearance was altered. Many late larval puffs were active in prepupae rather than in larvae, whereas some of the puffs, normally appearing in prepupae, were active in the larval stage.Accordingly, we propose to distinguish two groups of puff loci. 1) Hormone dependent puffs: These do not develop in larval lethals and are active only after puparium formation in pupariated lethals. 2) Autonomous puffs: Their appearance depends more on the time of development, than on hormonal background. It is suggested that the induction of hormone dependent puffs and of puparium formation is possible at low ecdysone levels, provided that the juvenile hormone level is also low.     

Endosomal vacuoles of the prepupal salivary glands of Drosophila play an essential role in the metabolic reallocation of iron

In the recent past, we demonstrated that a great deal is going on in the salivary glands of Drosophila in the interval after they release their glycoprotein‐rich secretory glue during pupariation. The early‐to‐mid prepupal salivary glands undergo extensive endocytosis with widespread vacuolation of the cytoplasm followed by massive apocrine secretion. Here, we describe additional novel properties of these endosomes. The use of vital pH‐sensitive probes provided confirmatory evidence that these endosomes have acidic contents and that there are two types of endocytosis seen in the prepupal glands. The salivary glands simultaneously generate mildly acidic, small, basally‐derived endosomes and strongly acidic, large and apical endosomes. Staining of the large vacuoles with vital acidic probes is possible only after there is ambipolar fusion of both basal and apical endosomes, since only basally‐derived endosomes can bring fluorescent probes into the vesicular system. We obtained multiple lines of evidence that the small basally‐derived endosomes are chiefly involved in the uptake of dietary Fe³⁺ iron. The fusion of basal endosomes with the larger and strongly acidic apical endosomes appears to facilitate optimal conditions for ferrireductase activity inside the vacuoles to release metabolic Fe²⁺ iron. While iron was not detectable directly due to limited staining sensitivity, we found increasing fluorescence of the glutathione‐sensitive probe CellTracker Blue CMAC in large vacuoles, which appeared to depend on the amount of iron released by ferrireductase. Moreover, heterologous fluorescently‐labeled mammalian iron‐bound transferrin is actively taken up, providing direct evidence for active iron uptake by basal endocytosis. In addition, we serendipitously found that small (basal) endosomes were uniquely recognized by PNA lectin, whereas large (apical) vacuoles bound DBA lectin.     

Biochemical and ontogenetic aspects of glycoprotein synthesis in Drosophila virilis salivary glands

After SDS-polyacrylamide gel electrophoresis two glycosylated glue proteins are found in the salivary glands of Drosophila virilis late third instar larvae. Synthesis of larval glue protein 1 occurs in three successive steps: at first a precursor protein with a molecular weight of about 138,000 daltons is formed. This is modified by two subsequent steps of glycosylation, the first one involving hexosamine, the second one hexoses. Studies with tunicamycin and β-hydroxynorvaline suggest that glycosylation occurs at threonine residues. Larval glue protein 2 has a molecular weight of approximately 15,000 daltons and is weakly glycosylated. The synthesis of glue proteins is stage specific. It starts at about 120 hr after oviposition and attains its maximal rate about 20 hr later. At this time the larvae leave the food. Between ecdysone release and puparium formation (146–151 hr) larval glue protein synthesis is terminated. Throughout the prepupal stage a different set of glycoproteins is synthesized. Thus, the larval-prepupal transition is accompanied by the reprogramming of glycoprotein synthesis in salivary glands. The secretion products formed during the two developmental stages seem to possess different biological functions.     

Glucosamine metabolism in Drosophila virilis salivary glands: Ontogenetic changes of enzyme activities and metabolite synthesis

In Drosophila virilis salivary glands the in vitro activities of enzymes involved in the glucosamine pathway were examined during the third larval instar and in the prepupa. While glutamine-fructose-6-phosphate aminotransferase (EC 5.3.1.19) becomes inactive at the time of puparium formation, glucosamine-6-phosphate isomerase (EC 5.3.1.10) and glucosamine-6-phosphate N-acetyltransferase (EC 2.3.1.3) show maximal activities in the prepupal gland. The activity of UDP-N-acetylglucosamine pyrophosphorylase (EC 2.7.7.23) may also decrease prior to puparium formation. Incubation of larval and prepupal glands in medium containing [³H]glucose + [¹⁴C]-uridine or [¹⁴C]glucosamine and subsequent separation of intermediates of the glucosamine pathway by chromatographic procedures reveal that the capacity of the glands to incorporate the isotopes into these intermediates decreases significantly at the time of puparium formation. The results suggest that in D. virilis salivary glands the formation of aminosugars is mainly controlled by the activities of the two enzymes glutamine-fructose-6-phosphate aminotransferase and UDP-N-acetylglucosamine pyrophosphorylase.     

Patterns of puffing activity in the salivary gland chromosomes of Drosophila

The patterns of puffing activity have been studied during the late larval and prepupal stages of Drosophila melanogaster. On the major salivary gland autosomes (chromosomes 2 and 3) 108 loci form puffs at some time during these developmental stages. The timing and pattern of activity of 83 of these puffs is found to be strictly dependent upon the age of the animals. Two major peaks in puffing activity occur. The first of these is at the time of puparium formation and the second in 8 hr. old prepupae. Both of these puffing peaks precede a moult by 4 hrs. 30 puffs are active before or at the time of both of these two moults. However, the sequence of appearance and regression of many of this group of puffs is different at the prepupal moult than at the pupal moult. 12 puffs occur only before or at the time of the prepupal moult and 13 puffs only before or at the time of the pupal moult. The functional significance of these periods of puffing activity is discussed and it is concluded that one function of this genetic activity in the salivary glands of metamorphosing Drosophila is the production of substances to be utilised during the histogenesis of the adult tissues.     

Activities of natural methyl farnesoids on pupariation and metamorphosis of Drosophila melanogaster

Methyl farnesoate (MF) and juvenile hormone (JH III), which bind with high affinity to the receptors USP and MET, respectively, and bisepoxy JH III (bisJH III) were assessed for several activities during Drosophila larval development, and during prepupal development to eclosed adults. Dietary MF and JH III were similarly active, and more active than bisJH III, in lengthening larval development prior to pupariation. However, the order of activity was changed (JH III > bisJH III > MF) with respect to preventing prepupae from eclosing as normal adults, whether administered in the larval diet or as topically applied at the white puparium stage. If endogenous production of all three larval methyl farnesoids was suppressed by a strongly driven RNAi against HMGCR in the corpora allata cells, most larvae did not attain pupariation. Farnesol (which has no demonstrated life-necessary function in larval life except in corpora allata cells as a precursor to methyl farnesoid biosynthesis) when incorporated into the diet rescued attainment of pupariation in a dose-dependent manner, presumably by rescuing endogenous production of all three hormones. A more mild suppression of endogenous methyl farnesoid production enabled larval attainment of pupariation. However, in this background dietary MF had increased activity in preventing puparia from attaining normal adult eclosion. The physiological relevance of using exogenous methyl farnesoids to block prepupal development to normally eclosed adults was tested by, instead, protecting in prepupae the endogenous titer of methyl farnesoids. JH esterase normally increases during the mid-late prepupal stage, presumably to clear endogenous methyl farnesoids. When JH esterase was inhibited with an RNAi, it prevented attainment of adult eclosion. Cultured adult corpora allata from male and female Aedes aegypti released both MF and JH III, and the A. aegypti nuclear receptor USP bound MF with nanomolar affinity. These A. aegypti data support the use of Drosophila as a model for mosquitoes of the binding of secreted MF to USP.     

Synthesis and secretion of salivary gland proteins in Drosophila gibberosa during larval and prepupal development

Summary The late larvae of Drosophila gibberosa Patterson and Mainland choose different pupariation sites than the larvae of Drosophila melanogaster Meigen. Since the larvae of D. gibberosa do not attach themselves to the substratum, the salivary glands contain only a small amount of the glue proteins before pupariation. Proteins comprising the salivary gland secretions of late larvae of these two species were compared and found to be qualitatively quite different. Only five polypeptides with the same molecular masses were identified in both species. The rate of protein synthesis in the salivary glands of D. gibberosa continued to increase through the late larval stage and pupariation. As a consequence, the total amount of protein contained in the salivary glands also continued to increase after pupariation. To demonstrate temporal changes in protein synthesis from 48 h before pupariation to 28 h after pupariation, newly synthesized polypeptides were pulse labeled by culturing salivary glands in vitro. The patterns of polypeptide synthesis fell into four major groups depending upon whether the synthesis of a protein stopped shortly after pupariation, stopped during late pupariation, increased at pupariation, or was initiated after pupariation. Changing patterns of protein synthesis are correlated with the known changes in gene puffing during this developmental period.     

Control of the developmental timer forDrosophila pupariation

Summary In the insectDrosophila, formation of the puparium marks the onset of metamorphosis and serves as a useful marker for developmental progress. The cells of the adult remain diploid and divide during the larval stage while the larval cells become polytene and do not divide. We use a high dose of gamma-irradiation (10 krad) to selectively delete the imaginal lineage from the developing larvae ofDrosophila melanogaster. We find that animals depleted of imaginal cells including those of the imaginal brain pupariate only if the larval cells are allowed to mature, demonstrating that the larval cells harbor the primary developmental timer for this process. However, proliferating imaginal cells can exert a negative influence on the timing of pupariation.     

The hormonal control of salivary gland secretion in Drosophila melanogaster: Studies in vitro

The larval salivary gland of Drosophila melanogaster synthesises a complex secretion, known as ‘glue’. which is secreted at puparium formation and then cements the puparium to its substrate. This secretion is made during the third larval instar and is stored in the gland cells as large granules. A few hours before puparium formation it is secreted into the gland's lumen by exocytosis. This process is induced by ecdysone and can be studied in vitro. Secretion is initiated about 3.5 hr after exposure of glands to ecdysone and is complete by 8 hr. The effects of varying the ecdysone concentration, of inhibitors of RNA or protein synthesis, and of withdrawing the hormone at various times after initial exposure on the process of secretion have been studied. We conclude that some event(s) occurring during the first 3 hr exposure to ecdysone is necessary to initiate secretion of the glue into the gland lumen. The possible relationship between this event(s) and the ecdysone induced changes in gene activity (puffs) which occur in the salivary glands at the same time is discussed.     

The timing of drosophila salivary gland apoptosis displays an l(2)gl-dose response

During Drosophila metamorphosis, larval tissues, such as the salivary glands, are histolysed whereas imaginal tissues differentiate into adult structures forming at eclosion a fly-shaped adult. Inactivation of the lethal(2)giant larvae (l(2)gl) gene encoding the cytoskeletal associated p127 protein, causes malignant transformation of brain neuroblasts and imaginal disc cells with developmental arrest at the larval-pupal transition phase. At this stage, p127 is expressed in wild-type salivary glands which become fully histolysed 12 - 13 h after pupariation. By contrast to wild-type, administration of 20-hydroxyecdsone to l(2)gl-deficient salivary glands is unable to induce histolysis, although it releases stored glue granules and gives rise to a nearly normal pupariation chromosome puffing, indicating that p127 is required for salivary gland apoptosis. To unravel the l(2)gl function in this tissue we used transgenic lines expressing reduced ( approximately 0.1) or increased levels of p127 (3.0). Here we show that the timing of salivary gland histolysis displays an l(2)gl-dose response. Reduced p127 expression delays histolysis whereas overexpression accelerates this process without affecting the duration of third larval instar, prepupal and pupal development. Similar l(2)gl-dependence is noticed in the timing of expression of the cell death genes reaper, head involution defective and grim, supporting the idea that p127 plays a critical role in the implementation of ecdysone-triggered apoptosis. These experiments show also that the timing of salivary gland apoptosis can be manipulated without affecting normal development and provide ways to investigate the nature of the components specifically involved in the apoptotic pathway of the salivary glands.     

Adjacent chromosomal regions can evolve at very different rates: Evolution of theDrosophila 68C glue gene cluster

Summary The 68C puff is a highly transcribed region of theDrosophila melanogaster salivary gland polytene chromosomes. Three different classes of messenger RNA originate in a 5000-bp region in the puff; each class is translated to one of the salivary gland glue proteins sgs-3, sgs-7, or sgs-8. These messenger RNA classes are coordinately controlled, with each RNA appearing in the third larval instar and disappearing at the time of puparium formation. Their disappearance is initiated by the action of the steroid hormone ecdysterone. In the work reported here, we studied evolution of this hormone-regulated gene cluster in themelanogaster species subgroup ofDrosophila. Genome blot hybridization experiments showed that five other species of this subgroup have DNA sequences that hybridize toD. melanogaster 68C sequences, and that these sequences are divided into a highly conserved region, which does not contain the glue genes, and an extraordinarily diverged region, which does. Molecular cloning of this DNA fromD. simulans, D. erecta, D. yakuba, andD. teissieri confirmed the division of the region into a slowly and a rapidly evolving protion, and also showed that the rapidly evolving region of each species codes for third instar larval salivary gland RNAs homologous to theD. melanogaster glue mRNAs. The highly conserved region is at least 13,000 bp long, and is not known to code for any RNAs.     

Developmental studies in Drosophila

A study of the puffing patterns of the salivary gland chromosomes of D. pseudoobscura was carried out through several larval, prepupal, and pupal stages of development. A total of 176 puffs were found, 111 of which changed during the stages studied. As described in previous investigations with other Drosophila species there are two major peaks of puffing activity. These two peaks occur during puparium formation and pupation. Additionally, a minor activity-peak occurs during mid-prepupal life. Attempts have been made to establish correlations between the puffing data and those obtained from electrophoretic and ultrastructural studies.Supported in part by grants GM-16736-03 and FR-05426-09 from the U.S. Department of Health, Education, and Welfare. Ann Jacob Stocker was a holder of a University of Texas predoctoral fellowship.     

The prepupal salivary glands of Drosophila melanogaster

Evidence is presented in support of the concept that the larval salivary gland of Drosophila melanogaster continues to function as an important secretory organ throughout prepupal stages and after pupation. Just after puparium formation, and at other later periods, the glands appear to be in the process of disintegration, but each time they recover until after pupation. Nuclear blebbing occurs through the time of survival of the glands, but is shown not to involve transport of RNA out of the nucleus. Transport in and out of the nucleus is clearly rapid and in a steady state as compared to the massive and intermittent export of cytoplasmic substance into the lumen of the gland.This work was supported by grants from the National Science Foundation (GB-23343, PCH-02044).     

Substrate-histochemical investigations and ultrahistochemical demonstrations of acid phosphatase in larval and prepupal salivary glands of Drosophila melanogaster

Summary A major function of the larval salivary glands of Drosophila melanogaster is known to be the production of a mucopolysaccharide that serves as an adhesive during puparium formation. In order to localize the mucosubstances during development substrate histochemical methods were used, and the site of acid phosphatase was demonstrated by the ultrahistochemical lead-salt method. It could be shown that the glue-granules in the corpus cells of larval salivary glands as well as the large secretion vacuoles in the prepupal corpus cells give a positive -amylase-resistent PAS-reaction, which indicates neutral mucosubstances. Granular PAS-positive deposits in the larval and prepupal collum cells were reduced after preincubation with -amylase and may represent glycogen, which has also been seen in electron micrographs of these cells. The Hale-reaction gave a weak indication that acid mucosubstances are present in the larval glue granules and in the large prepupal secretory vacuoles. After digestion of sialic acid with -neuraminidase the weak indication was absent showing that the acid mucosubstances had been sialomucines. Ultrahistochemical demonstration of acid phosphatase indicated the presence of this enzyme in Golgi fields and lysosomal structures. Acid phosphatase seems to be missing in the large secretion vacuoles of the prepupal salivary gland.It is concluded, that the large vacuoles in the corpus cells of prepupal salivary glands represent a secretion product, obviously a mucosubstance. The lysosomal structures, containing acid phosphatase, may be accumulated in preparation for the autolysis of the gland which begins about two hours after the pupal moult, i.e. 15 hours after puparium formation.This investigation was supported by grants from the Deutsche Forschungsgemeinschaft (Ga 97/6).     

Growth rate adjustment of two Drosophila parasitoids in response to the developmental stage of hosts

1. Generalist koinobiont parasitoids often exhibit high flexibility in their development; their larvae shorten or prolong the developmental period depending on the host quality at parasitisation. However, flexibility of the growth rate of parasitoid larvae has rarely been investigated so far. 2. This study investigated how the koinobiont parasitoid wasps Asobara japonica and Leptopilina ryukyuensis regulate their larval growth when they parasitise host Drosophila larvae with varying larval periods. 3. In both parasitoid species, the preimaginal period was longer when they parasitised 1‐day‐old larvae of Drosophila rufa than when they parasitised older larvae of D. rufa or when they parasitised larvae of Drosophila simulans, a species with a shorter larval period than D. rufa. After host pupariation, A. japonica accelerated its growth, thereby showing a biphasic growth curve. On the other hand, L. ryukyuensis did not accelerate its growth after host pupariation. 4. Growth retardation of parasitoid larvae in 1‐day‐old D. rufa larvae would contribute to avoiding excess growth before host pupariation, because the excess growth of parasitoid larvae would have negative effects on host growth. The growth rate acceleration of A. japonica after host pupariation suggests that they enhance resource utilisation in a host that has reached maximum body mass. It remains uncertain as to why L. ryukuensis does not show clear accelerated growth after host pupariation. Nonetheless, these results suggest that parasitoid larvae have the ability to detect the developmental stage of hosts in a species‐specific manner.     

Ultrastructure of salivary glands of Drosophila lebanonensis during normal development and after in vivo ecdysterone administration

Changes in the morphology of the salivary glands of Drosophila lebanonensis have been followed at both the light and electronmicroscopic level during a period of 30 hr before puparium formation and during puparium formation itself. Three striking differences were observed in comparison to other Drosophila species studied: (1) the secretion product of Drosophila lebanonensis has a different stainability to PAS reagent and uranyl acetate and no internal structures or “caps” can be observed; (2) the release of this secretion product is not restricted to a time period shortly before puparium formation but is a continuous process starting about 24 hr before puparium formation; and (3) the histolysis of these glands starts immediately after puparium formation, whereas in other Drosophila species this event starts 5 hr later.Puparium formation of Drosophila lebanonensis is controlled by the circadian oscillation. Injection of ecdysterone before the “gate” period results in changes in the cuticle as observed during normal development, but is not followed by the histolysis of the glands. Injection of ecdysterone after the “gate” is not followed by changes in the cuticle but histolysis is induced.     

Ecdysterone responsive functions in the mutantl(1)su(f) ts67g ofDrosophila melanogaster

Summary Transferring the temperature sensitive mutantl(1)su(f) ^ts67g from 25° C to 30° C before or early in the third larval instar blocks the increase in the ecdysterone titer that normally occurs at the end of the larval period. Feeding exogenous ecdysterone to these hormone-deficient larvae results in the formation of pseudopupae. The mutant was used to study ecdysterone-inducible functions in late larval salivary glands by preparing three animal samples with different hormone titers: the titer was low in one sample because of an earlier temperature shift, high in a second sample because the larvae were subsequently transferred to ecdysterone-supplemented food, and also high in a third sample that was kept at 25°C, providing a control for normal development. The effect of the different hormone conditions was studied by³⁵S-methionine labeling of the salivary gland proteins during the larval to prepupal transition and the prepupal period. The results indicate that synthesis of several of the proteins normally appearing during the transition and prepupal period is induced by exogenous ecdysterone.