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.     

Autonomous puffing patterns in thoracic and abdominal polytene bristle cell chromosomes of the flesh fly Sarcophaga barbata

The puffing patterns of the thoracic and abdominal polytene bristle cell chromosomes were investigated in Sarcophaga barbata during a 10-day period of pupal development. The autonomous differentiation of imaginal disk descendants is visualized microscopically at the chromosomal level by the cell autonomous puff activities of the polytene bristle cell chromosomes. The sequence of chromosomal activities is strictly stage specific in both cell types. The changes in the puffing pattern are closely corelated with development. The puffing pattern changes synchronously in all bristle cells of a certain body region, e.g., the scutellum or the fifth abdominal tergit. However, there is no synchrony between the puffing pattern changes of the thoracic and abdominal bristle cells. The loci of the abdominal bristle cells are activated one day later than those of the thoracic cells. Each particular puffing pattern truly represents a particular developmental state of the bristle, regardless of body location. That is, the bristle cell chromosomes of various body segments control the timing of their puffing activities autonomously and puff formation and puff regression are not hormonally synchronized.     

Patterns of puffing activity and chromosomal polymorphism in Drosophila subobscura II. Puffing patterns at the prepupa stage

Puffing activity patterns of the five large polytene chromosomes of Drosophila subobscura were studied during the late third-larval instar and through the prepupal period. A total of 166 loci active in some of the eleven stages studied were described. The distribution of these active loci per chromosome is the following: 25 on chromosome A, 33 on chromosome J, 31 on chromosome U, 34 on chromosome E and 43 on chromosome O. Seven principal patterns of puffing activity were defined taking into account the different curves of the puffing histograms. Gene activities per chromosome as well as total were analysed. Three peaks of gene activity at the beginning, middle and ending of prepupation can be observed. U is the most active chromosome and A (the sex chromosome), and J the least active. Chromosomes E and O show a medium activity. A possible biological explanation for these results is discussed.Publication No. 107, Departamento de Genética, Universidad de Valencia (Spain).     

Developmental puffing activity in the salivary gland and Malpighian tubule chromosomes ofAcricotopus lucidus (Diptera,Chironomidae)

A detailed map of the salivary gland chromosomes ofAcricotopus lucidus is presented. Differences in puffing and developmental Puffing sequences of the three salivary gland lobes were investigated from mid fourth larval instar to pupation and compared with the puffing pattern of the Malpighian tubules. The intraglandular differentiation is quite extensive; the differences in the pattern of gene activity between the anterior lobe and the main and side lobes are as great as between the salivary gland and the Malpighian tubules. In the main and side lobes all developmental puffing changes proceed synchronously whereas in the anterior lobe both asynchronous and synchronous changes occur. In the anterior lobe the asynchronous regression of BR 3 and BR 4 is followed by a characteristic sequence of activation and inactivation of puffs.     

Comparative study of the function of polytene chromosomes in laboratory stocks of Drosophila melanogaster and the l(3)tl mutant (lethal tumorous larvae)

A study of the puffing pattern of the salivary gland autosomes of D. melanogaster was performed through the last 24 hours of larval development and 0-hour prepupae. Since both prominent and small puffs were taken into account, the total puff number amounted to 275. Of these, 116 are almost constant in size during the 24 hours observation period, 106 increase in size or appear before pupation. 37 puffs are active in 96 hour larvae and disappear or decrease sharply in size by 115–118 hours. 12 biphasic puffs have been found with higher activity in 96 hour larvae and 0-hour prepupae and lower activity by 115–118 hours. Three extremely irregular puffs have been detected in chromosome 4. The data obtained evidence that a larger number of D. melanogaster polytene chromosome loci are active during larval development than it has been thought earlier. It has also been shown that only 38% of autosomal puffs change before the beginning of metamorphosis. The functional significance of small puffs and strain specificity of puffs are 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.     

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     

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.     

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.     

Patterns of puffing activity in the salivary gland chromosomes of Drosophila

The autosomal salivary gland chromosome puffing patterns of Drosophila simulans are described and compared with the puffing patterns of the sibling species D. melanogaster. During the late third larval instar and the prepupal period the patterns of puffing activity of these two species are similar — approximately 50% of the puffs common to both species showing identical activities. The remaining puffs differ in their timing of activity, or in their mean sizes, or in both of these parameters. A number of puffs (14) found in D. simulans have not been regularly observed in the Oregon stock of D. melanogaster but are active in other D. melanogaster strains. One puff (46 A) of D. melanogaster was absent from D. simulans and forms a heterozygous puff in hybrids, when the homologous chromosomes are synapsed. When the homologues are asynapsed a puff at 46 A is restricted to the melanogaster homologue. The puff at 63E on chromosome arm 3L is considerably smaller in D. simulans than in D. melanogaster and this size difference is autonomous in hybrids. Other puffs not common to both species behave non-autonomously in the species hybrid, even when the homologous chromosomes are asynapsed.     

Comparative study of protein synthesis and heat-shock puffing activity in Drosophila salivary glands treated with chloramphenicol

The effects of chloramphenicol (CAP) on puffing activity and incorporation of tritiated amino acids in proteins synthesized by cultured larval salivary glands of Drosophila melanogaster were examined. CAP concentrations exceeding 1 mM were found to inhibit cellular protein synthesis and to induce the special group of heat-shock puffs in the polytene chromosomes. Recovery from a transient treatment with 5 mM CAP for 120 min led to rapid regression of the puffs and resumption of protein synthesis giving a pattern of labelled polypeptides similar to that produced by cells submitted to a temperature shift from 25 to 37 degrees C. Only slight inhibition of protein synthesis was found with thiamphenicol, the methylsulphonyl analogue of CAP, which induced a single puff in the 93D region, but did not alter the pattern of polypeptides. In contrast to the results obtained with CAP, recovery from a transient inhibition of protein synthesis by cycloheximide led to the synthesis of normal proteins as produced by control cells at 25 degrees C. Different effects of CAP which may interfere with protein synthesis and puffing activity are discussed.     

Developmental puffing patterns in salivary gland chromosomes of Rhynchosciara hollaenderi

An analysis of puff formation and regression has been carried out in 3 morphologically distinct regions of the Rhynchosciara hollaenderi salivary gland during mid-larval through pupal development. Puffing differences among these 3 regions have been found and analysed for both RNA and DNA puffs. The presence of such differences suggests that the gland regions may also be functionally differentiated. — Developmentally specific sequences of puffs have been distinguished and correlated with morphological and physiological events which occur during the development of Rhynchosciara. The DNA puffs as well as the RNA puffs enlarge and regress at predictably specific developmental stages. The presence of particular puffing sequences in the late larval to pupal period has been compared with the occurrence of known changes in the developmental ecdysone titre for Rhynchosciara. Certain aspects of this developmental picture appear to fit the ecdysone-stimulated puffing model for Drosophila, but other aspects indicate that the Drosophila-based model may not be completely applicable to Rhynchosciara.     

Distribution patterns of three subfractions of drosophila nonhistone chromosomal proteins: possible correlations with gene activity.

The distribution of three molecular weight subfractions of the Drosophila nonhistone chromosomal proteins (NHC proteins) has been studied using an immunofluorescent technique (Silver and Elgin, 1976). In all three cases, the fluorescence distribution patterns obtained are distinct and reproducible. The results imply that different NHC protein components have different distributions along the polytene chromosomes. A highly selective pattern is obtained using antiserum against subfraction ?; puffs (loci highly active in RNA synthesis) and many nonpuffed chromomeres which are known to puff at other times during the third larval instar or prepupal stages are brightly fluorescent. New RNA synthesis can be induced at 87A, 87B-C1 and other chromomeres by heat shock treatment; these loci, previously stained at low levels, are subsequently stained brightly using the ? serum. The staining of the heat shock puffs appears to be superimposed upon the prior ? pattern. The results suggest that a change in chromosomal structure, as indicated by staining using the ? serum, is associated with gene activity as indicated by puffing. This different chromosomal structure may be the consequence of either a redistribution of a ? antigenic determinant [a new association of specific protein(s) with the active sites] or a change in chromatin configuration [making the ? antigenic determinant(s) newly available to the antibody probe].