Two-step regulation of ecdysone-inducible late puffs in salivary glands of Drosophila melanogaster

Our previous study showed that some ecdysone-inducible late puffs could also be induced by a mild detergent (digitonin) in Drosophila salivary glands. However, they could only be induced at the stage immediately prior to when developmentally programmed puffing occurred, suggesting that these late puff loci were under two-step regulation. Using an in vitro culture of salivary glands, we have examined whether ecdysone or the protein products of early puff genes participate in either of the two steps of late puff regulation. This study has revealed that (i) the acquisition of digitonin-responsiveness (the first step) could be induced in vitro by incubating salivary glands with ecdysone; (ii) the first step could also be induced by protein synthesis inhibition even in the absence of ecdysone; (iii) the second step required both ecdysone and protein synthesis unless treated with digitonin; and (iv) the first step, rather than the second step, determines the timing of normal puff formation in the loci. These results suggest that, during normal development, ecdysone controls both steps by activating two types of early genes; the first type, whose function can be mimicked by cycloheximide, renders the loci responsive to digitonin and the second type, whose function can be mimicked by digitonin, activates the loci to form puffs.     

Digitonin treatment activates specific genes including the heat-shock genes in salivary glands of Drosophila melanogaster

A large number of chromosomal sites were found to form puffs in Drosophila salivary glands after treatment with the mild detergent digitonin and incubation in a defined medium for 2 hr. The cytological locations of these puffs were determined, and the puff size was measured at 43 loci in both digitonin-treated salivary glands and intact glands. On the basis of comparisons of puffing between digitonin-treated and intact salivary glands, the puffs were classified into three categories: (1) digitonin-unaffected preexisting puffs (8 sites), (2) digitonin-activated preexisting puffs (6 sites), and (3) digitonin-induced new puffs ("digitonin puffs", 29 sites). The digitonin puffs included some of the developmentally regulated puffs and all the heat-shock puffs known in Drosophila melanogaster. The activation of the specific loci by digitonin treatment suggests that gene expression at these loci is suppressed in salivary glands by a mechanism(s) sensitive to digitonin.     

Activation of Heat-Shock Genes by Digitonin is Selectively Repressed in Preheated Drosophila Salivary Glands

Treatment of Drosophila salivary glands with a mild detergent, digitonin, activates puffing at 35 chromosome loci. These digitonin-activated puffs include all of the nine heat-shock puffs known in D. melanogaster . Here we show that the activation of heat-shock genes, but not of other digitoninstimulated puffs, is repressed in salivary glands which have been subjected to and have recovered from heat shock before being treated with digitonin. The findings indicate that, (a) the activation of heat-shock genes by digitonin, as that by temperature elevation, is self-regulated by the heat-shock proteins (HSPs). (b) the gene repressive activity of HSPs is heat-shock-gene specific, and (c) the repression mechanism of heat-shock genes by HSPs is resistant to digitonin, in contrast to that the suppression of heat-shock genes is prevented by the detergent in non-heat-shocked salivary glands. The selective repression of heat-shock genes in preheated salivary glands suggests that the heat-shock genes and other digitonin-activated genes may be controlled by a different mechanism(s).     

Puffing activities and binding of ecdysteroid to polytene chromosomes of Drosophila melanogaster

Salivary glands of third instar Drosophila melanogaster larvae were incubated in vitro in the presence of 5 x 10(-6) M 20-hydroxy-ecdysone. Steroid hormone was localized on the polytene chromosomes of the salivary gland by a combination of photoaffinity-labeling and indirect immunofluorescence microscopy. Steroid hormone binding to chromosomal loci and their puffing activity was correlated for the larval/prepupal puffing cycle characterized by puff stages 1-10. In general, there was a good correlation between the sequential and temporal puffing activity induced by 20-hydroxy-ecdysone and the binding of ecdysteroid hormone to these puffs. Ecdysteroid hormone was detected at intermolt, and at early and late puffs with two notable exceptions. Ecdysteroid was not detected at the two well-studied puffs at 23E and at 25AC, the former being an early puff, which is activated in the presence of 20-hydroxy-ecdysone, and the latter being an intermolt puff, which regresses more rapidly in the presence of hormone. Ecdysteroid hormone was present at puffs as long as the respective puff was active. Also, it apparently accumulated at late puff sites after induction. Since ecdysteroid binding to chromosomal loci is temporal as well as sequential during the larval/prepupal puffing cycle, additional factors besides steroid hormone are necessary for sequentially regulating puffing and concomitant gene activity during development from larvae to prepupae.     

Ecdysone-regulated chromosome puffing in the salivary glands of the Mediterranean fruit fly, Ceratitis capitata.

The effect of ecdysone on the puffing activity of the polytene chromosomes of Ceratitis capitata has been studied in organ cultures of late-larval salivary glands. Culture of glands from 120-h-old larvae (puff stage 1) in the presence of ecdysone resulted in the initiation of the late-larval puffing cycle that is normally observed in 145-h-old larvae (puff stage 4). During a 7-h period in the presence of ecdysone, the puffing patterns of most loci resembled the in vivo patterns observed in the period between puff stages 4 and 10, indicating that the first puffing cycle can be initiated by the hormone and proceed almost to completion, in vitro. Culture of salivary glands in the presence of ecdysone and a protein-synthesis inhibitor, as well as ecdysone withdrawal and readdition experiments, indicated that most of the ecdysone-regulated puffs could be categorized into three classes: (i) the puffs that were suppressed immediately by ecdysone, even in the absence of protein synthesis; (ii) the puffs that were induced directly by ecdysone; and (iii) the puffs that were induced indirectly by ecdysone, that is, they were induced after a lag period of a few hours and required protein synthesis for their induction.     

The dynamics of the induction and regression of puffs 87A, 87C and 93D in the polytene chromosomes of Drosophila melanogaster under the action of anoxia and high temperature]

A study was made of the heat shock puff activity in salivary glands of Drosophila melanogaster larvae after 5 and 20 min treatments with anoxia (dipping into physiological solution), heat shock (37 degrees C), and simultaneously with both the agents. The simultaneous treatment with heat shock and anoxia, as well as treatment with anoxia only blocked the induction of heat shock puffs. They appeared 10-15 min after the treatment during recovery under aerobic conditions. There was a super-additive effect of the simultaneous treatment on the heat shock puffing duration. A specific regulation of the 93D locus was observed. The 93D puff was induced by a 5 min simultaneous treatment with anoxia and heat shock and, as a rule, was not induced by the analogous 20 min treatment. The role of anoxia in blocking heat shock puff induction under simultaneous effects of heat shock and anoxia is discussed.     

Developmental Studies in Drosophila

The salivary gland chromosomes of 3rd instar Drosophila pseudoobscura larvae were observed for puffing changes after injection of larvae with ecdysterone solution. Chromosomes from the salivary glands of 3rd instar larvae and prepupae were similarly examined after incubation in ecdysterone-containing medium. The larvae, after treatment, showed advancement of the puffing process with the occurrence of a pattern similar to that observed during the pre-spiracle eversion period of normal development. At least 92 puffs showed changes in size. For the prepupae, the puffing changes resembled those occurring normally during the late prepupal period. A group of puffs were selected for detailed study. Among these were four puffs on the XR chromosome which exhibited large increases before spiracle eversion and pupation in normal development. As in normal development, two of these became the most prominent puffs observed within h after hormone treatment. In chromosomes from larval glands, the other two XR chromosome puffs were among the largest puffs to appear later in the sequence. However, in chromosomes from prepupal glands one of these later puffs failed to appear. The significance of this large number of hormone-inducible puffing changes at two different periods in development is discussed.     

Induction of the Drosophila heat shock response in isolated polytene nuclei

When Drosophila salivary glands are disrupted in cytoplasm from heat-shocked Drosophila Kc cells in culture, puffs are induced in the polytene nuclei at the heat shock loci. The in vitro response increases with time of incubation, reaching in vivo levels after 2 hr, and is sensitive to α-amanitin. Cytoplasm from control Kc cells induces poorly, but prolonged exposure to air or the addition of hydrogen peroxide stimulates induction to the levels observed with cytoplasm from heat-shocked Kc cells. Autoradiography confirms that the heat shock loci induced to puff in vitro are the most actively transcribing sites in the genome.     

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.     

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.     

An overview of gene activity in the fat body of Drosophila gibberosa

In the larval fat body of Drosophila gibberosa, polytene chromosome structure and activity exhibit cytological differences from chromosomes of midgut and salivary glands. These differences include long-persisting puffs, transient puffs and long-persisting band modulations. Some early ecdysteroid-induced puffs are present in all three organs but few late puffs are present in the fat body. Comparative studies reveal, therefore, that late larval-early pupal puffing is enhanced in salivary glands relative to gut, fat body and Malpighian tubules. After the fat body breaks up in the prepupa, the rate of programmed cell death and the corresponding slow decline of chromosomal activity also differ from cell to cell and from other organs.by M.L. Pardue     

Mutations affectingβ-alanine metabolism influence inducibility of the 93D puff by heat shock inDrosophila melanogaster

Effect of mutations at the ebony or black locus on induction of heat shock puffs in polytene nuclei of salivary glands ofDrosophila melanogaster larvae were examined by [³H]uridine autoradiography. The levels of-alanine in the body are known to be increased by mutation at the ebony locus but decreased by mutation at the black locus. The presence of mutant allele/s at either locus in the homo- or heterozygous condition prevented induction of the 93D puff by heat shock. Elimination of the mutant allele at the ebony or black locus by recombination or by reversion of a P element insertion mutant allele of ebony restored the heat shock inducibility of the 93D puff. In vivo or in vitro administration of excess-alanine to salivary glands of wild-type larvae also resulted in the 93D site being refractory to heat shock induction. In agreement with earlier results, noninduction of the 93D puff during heat shock due to the-alanine effect was accompanied by unequal puffing of the 87A and 87C loci. The selective inducibility of the 93D puff by benzamide was not affected by ebony or black mutations or by excess-alanine in wild-type larvae     

Puffing activity in the salivary gland chromosomes of Rhynchosciara under experimental conditions

By using the techniques of ligation of the larvae (brain and endocrine glands extirpation) and salivary gland implantation, the hormonal dependence of the activity of certain puffs of Rhynchosciara was investigated. Our results have shown that the puffing behaviour — activation and deactivation — varies according to the developmental stage in which the larvae were ligated. When the larvae were ligated just before the drastic changes in the puffing pattern, which occur prior to pupation, these changes fail to occur. When the larvae were ligated after the onset of these changes we have observed: a) some of the puffs active at the time of the ligature regress promptly, earlier than their normal timing observed in controls; b) others remain active indefinitely and c) there are still some which regress accordingly to the normal timing.The puff B2 which behaves as those in b was double checked by means of implantation experiments. Salivary glands which had puff B2 at its maximum expansion were implanted into younger larvae and that puff also remained active in the body cavity of these larvae. Hypotheses to explain the results obtained are discussed.     

Structure and activity of salivary gland chromosomes of Drosophila gibberosa

In Drosophila gibberosa the maximum secretory output of the salivary glands is in the prepupa rather than in the late third-instar larva. Using salivary chromosome maps provided here we have followed puff patterns from late second-instar larvae through the time of histolysis of the salivary glands 28–32 h after pupariation and find low puff activity correlated with low secretory activity throughout much of the third larval instar. Ecdysteroid-sensitive puffs were not observed at the second larval molt but do appear prior to pupariation initiating an intense cycle of gene activity. The second cycle of ecdysteroid-induced gene activity a day later, at the time of pupation, appears somewhat damped, especially for late puffs. Salivary chromosome maps provided here may also be used to identify homologous loci in fat body, Malpighian, and midgut chromosomes.