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 puff genes 2000.

The Ashburner model for the hormonal control of polytene chromosome puffing has provided a strong foundation for understanding the basic mechanisms of steroid-regulated gene expression (Cold Spring Harbor Symp. Quant. Biol. 38 (1974) 655). According to this model, the steroid hormone 20-hydroxyecdysone (referred here as ecdysone) directly induces the expression of a small set of early regulatory genes. These genes, in turn, induce a much larger set of late target genes that play a more direct role in controlling the biological responses to the hormone. The recent characterization of two early puff genes, E63-1 and E23, and three late puff genes, D-spinophilin, L63, and L82, provide further confirmation of the Ashburner model. In addition, these studies provide exciting new directions for our understanding of ecdysone signaling. Overexpression studies of E63-1 implicate this gene in directing calcium-dependent salivary gland glue secretion. In contrast, overexpression of E23 indicates that this ABC transporter family member may negatively regulate ecdysone signaling by actively transporting the hormone out of target cells. Finally, genetic studies of the L63 and L82 late genes reveal unexpected possible functions for ecdysone in controlling developmental timing and growth. This review surveys the recent characterization of these ecdysone-inducible genes and provides an overview of how they expand our understanding of ecdysone functions during development.     

The 82F late puff contains the L82 gene, an essential member of a novel gene family.

Metamorphosis in Drosophila results from a hierarchy of ecdysone-induced gene expression initiated at the end of the third larval instar. A now classical model of this hierarchy was proposed based on observations of the activity of polytene chromosome "puffs" which distinguished "early" puffs as those directly induced by ecdysone and "late" puffs as those which become active as a secondary response to the hormone. We report here the isolation and characterization of the L82 gene corresponding to the extensively characterized late puff at 82F. L82 is a complex gene that spans at least 50 kb of genomic DNA, produces at least seven different nested mRNAs, and has homology to a novel gene family. In contrast to most previously characterized puff genes, the broad developmental expression pattern of L82 suggests that it is controlled by both ecdysone-dependent and ecdysone-independent regulatory mechanisms. L82 mutations were identified by transgene rescue of developmental delay and eclosion lethal phenotypes.     

The Drosophila Eip78c Gene Is Not Vital but Has a Role in Regulating Chromosome Puffs

We have generated a number of chromosomal aberrations that disrupt the early-late ecdysone-induced 78C puff gene (Eip78C, ecdysone-induced protein, FlyBase name for the E78 gene of STONE and THUMMEL 1993), which encodes the two members of the nuclear hormone receptor superfamily Eip78C-A and Eip78C-B. The aberrations include deletions of the ligand-binding/dimerization domain of both, inversions that split Eip78C-A but retain residual Eip78C-B expression, and a small deletion specific for Eip78C-B. We find that wild-type Eip78C functions are completely dispensable for normal development under laboratory conditions. However, we show that Eip78C-B is required for the maximal puffing activity of a subset of late puffs (63E and 82F) since these puffs are reduced in size in Eip78C-B mutant backgrounds. Paradoxically the same late puffs are reduced, as well as at least one other, when the Eip78C-B cDNA is overexpressed from a heat shock promoter. These data indicate either that Eip78C function is redundant or that it plays a subtle modulating role in the regulation of chromosome puffing.     

Cytogenetic analysis of two ecdysone-regulated puffs 62C and 62E in Drosophila melanogaster

Genetic analysis has been performed to reveal vital genes around two puffs, a late 62C puff and an early-late 62E puff. Their roles in hormonal regulatory mechanisms have been estimated. A locus represented by four lethal mutations has been found in the vicinity of the 62E puff. The mutants display disturbed puffing, which suggests the involvement of this locus in hormonal regulatory mechanisms. In the 62C puff region. 26 mutations have been found that proved to be allelic to mutations in the D-Titin gene. The giant D-Titin gene is essential for the sarcomeric organization of striated muscles. According to the results of in situ hybridization with polytene chromosomes, the D-Titin gene occupies the entire 62C puff. The phenotypic characteristics of the novel mutants suggest that this protein is polyfunctional, and its role is not restricted to processes in the muscular tissue. It may also be involved in the morphogenesis of leg imaginal disks, and it is necessary for condensation and separation of sister chromatids during mitosis. Mutations in the ecdysone-induced BR-C and E74 genes cause disturbances similar to those found in this study. In addition, mutations of these genes can affect the D-Titin gene activity, which suggests that the three genes are involved in similar morphogenetic and myogenetic processes.     

Cytogenetic Analysis of Two Ecdysone-Regulated Late Puffs 62C and 62E in Drosophila melanogaster

Genetic analysis has been performed to reveal vital genes around two puffs, a late 62C puff and an early-late 62E puff. Their roles in hormonal regulatory mechanisms have been estimated. A locus represented by four lethal mutations has been found in the vicinity of the 62E puff. The mutants display disturbed puffing, which suggests the involvement of this locus in hormonal regulatory mechanisms. In the 62C puff region, 26 mutations have been found that proved to be allelic to mutations in theD-Titin gene. The giant D-Titin gene is essential for the sarcomeric organization of striated muscles. According to the results of in situ hybridization with polytene chromosomes, the D-Titin gene occupies the entire 62C puff. The phenotypic characteristics of the novel mutants suggest that this protein is polyfunctional, and its role is not restricted to processes in the muscular tissue. It may also be involved in the morphogenesis of leg imaginal disks, and it is necessary for condensation and separation of sister chromatids during mitosis. Mutations in the ecdysone-induced BR-C and E74 genes cause disturbances similar to those found in this study. In addition, mutations of these genes can affect the D-Titin gene activity, which suggests that the three genes are involved in similar morphogenetic and myogenetic processes.     

Molecular interactions within the ecdysone regulatory hierarchy: DNA binding properties of the Drosophila ecdysone-inducible E74A protein

The E74 early ecdysone-inducible gene plays a key role in the regulatory hierarchy activated by ecdysone at the onset of Drosophila metamorphosis. We show here that E74A protein binds to three adjacent sites in the middle of the E74 gene. The consensus sequence for E74A protein binding, determined by random-sequence oligonucleotide selection, contains an invariant purine-rich core sequence, C/AGGAA. This sequence is also present in the binding sites of two mammalian proteins that, like E74A, are related to the ets oncoprotein. Antibody staining of larval salivary gland polytene chromosomes revealed that E74A protein binds to both early and late ecdysone-inducible puffs. This study supports Ashburner's proposal that the early puffs encode site-specific DNA binding proteins that directly interact with the early and late ecdysone-inducible puffs.     

Digitonin Activates Different Sets of Puff Loci Depending on Developmental Stages in Drosophila melanogaster Salivary Glands

We showed previously that treatment of Drosophila melanogaster salivary glands with a mild detergent, digitonin, induces heat shock puffs and many developmentally regulated puffs. To find if the mechanism underlying the puff induction by digitonin is related to the temporal control of gene expression in salivary glands, we examined effects of digitonin on salivary glands at various puff stages from late third instar larva to white prepupa. The results indicate that (a) all the heat shock puffs are induced by digitonin irrespective of the developmental stage of the treated glands, (b) intermolt and early puff loci are always irresponsive to digitonin, and (c) late puff loci respond to digitonin to form puffs only before the stage of their developmentally programmed puffing. Based on the stage at which the locus becomes digitonin responsive, the digitonin-responsive late puff loci were divided into two groups: group A loci, responsive to digitonin continuously from PS1 until programmed puffing begins, and group B loci, responsive to digitonin only in a short period of time immediately before the programmed puffing. The results suggest that a digitonin-sensitive suppression mechanism(s) is involved in the temporal control of gene expression in Drosophila salivary glands.     

Developmental changes in midgut chromosomes of Drosophila gibberosa

In Drosophila gibberosa, differences between midgut and salivary gland chromosomes fall into two categories: tissue-specific band modulations which persist throughout the 90 h developmental period that we studied and tissue-specific puffs. Puffs that are common to both tissues tend to appear earlier in the midgut. Some major early ecdysteroid-induced puffs appear simultaneously in both tissues at the end of the third larval instar; however, the many late puffs that follow in the salivary glands are absent from the midgut. Intense puff activity in the early third larval instar midgut declines at the time of the hormonal pulse that initiates intense gene and secretory activity in salivary glands; the sloughing of midgut cells ensues.     

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.     

Cytogenetic analysis of the 2B3-4 — 2B11 region of the X chromosome of Drosophila melanogaster

Puffing patterns have been studied both in homozygotes t10/t10, a gene located in the area of the early ecdysone puff 2B5, and in a yellow (y) control stock, at the end of the third instar and during prepupal development. In mutants t10 at the end of the third instar puffing develops normally in general, however, 21 puffs (5 early and 16 late ones) underdevelop or do not develop at all, some larval intermoult puffs regressing slower. The next cycle of puffs (mid prepupal) in mutants t10 proceeds normally, but in the late prepupal cycle 21 puffs underdevelop again or are not formed at all. A model for the induction of early ecdysone puffs is proposed, assigning a key role to the 2B5 puff product in stimulating other early puffs. It is suggested that defects in the activity of early puffs in the mutant t10 may cause underdevelopment of late puffs.Dedicated to Professor W. Beermann on the occasion of his 60th birthday     

Sequential gene activation by ecdysone in polytene chromosomes of Drosophila melanogaster. I. Dependence upon ecdysone concentration

The response of the three major classes of puff in salivary gland chromosomes of larval Drosophila melanogaster to varying β-ecdysone concentrations has been studied in in vitro cultured glands. Two (25AC and 68C) of the intermolt puffs regress at a rate dependent upon the hormone concentration. Three rapidly reacting puffs (23E, 74EF and 75B) respond in a graded way to β-ecdysone concentrations over a range of at least 600 ×. In contrast, five late-reacting puffs (62E, 78D, 22C, 63E, and 82F) do not respond below 5 × 10^?8M and at 2.5 × 10^?7M react maximally. The 50% response of the early puff sites 74EF and 75B and of the late puff sites occurs at 1 × 10^?7M. Two points are discussed in detail: whether ecdysone is necessary as a sustained stimulus or only as a trigger for the sequential puffing response and an evaluation of the absolute ecdysone concentration necessary for induction.