Control of polytenic replication in dipteran larvae. I. Increased number of cycles in a mutant strain of Drosophila melanogaster

Previous studies have demonstrated that a consistent maximum number of polytenic replication cycles occurs in the salivary gland nuclei of a wild-type strain of D. melanogaster. Since that number is achieved within the larval period, the DNA synthesis of the prepupal period is believed to be that of propagation of the final cycle. Photometric determinations have been made, in this study, of the salivary gland nuclei of larvae and prepupae of the tu-h strain in which the larval period has been extended as a consequence of delay or failure of pupation. The DNA values indicate that a higher maximum number of polytenic replications is achieved in such nuclei. It is inferred, thereby, that initiation of polytenic replication is a function of the larval state and, since it is terminated by the intervention of metamorphosis, a hormonal dependence is suggested.     

Control of polytenic replication in dipteran larvae. II. Effect of growth temperature

A comparison has been made, by Feulgen photometry, of the polytene nuclei of the salivary glands of a wild-type strain of Drosophila melanogaster grown at 17°C and 25°C, respectively. Despite the fact that the time period of the larval stage was more than doubled at the lower temperature, the DNA values were the same in magnitude and similar in distribution of replication classes at each of the stages studied. The data have been interpreted as indicating that, so long as the larval state prevails, initiation of polytenic replication occurs upon completion of the previous cycle.     

DNA synthesis in polytenic chromosomes of Anopheles atroparvus

DNA synthesis in polytenic chromosomes of Anopheles atroparvus has been studied during the third and fourth larval stages. The beginning of the replication cycle coincides with the moult. With increasing larval age the frequency of nuclei in synthesis decreases continuously to reach 1 per cent in the fourth instar at 48 hours of age. The beginning of synthesis is characterized by asynchrony both among larvae and among nuclei within the same larva. At the beginning of replication the polytenic chromosomes have a discontinuous labelling pattern. The same pattern was observed at the end of reduplication. Whole nuclei and single chromosomal regions seem to reach their maximum degree of polyteny during the third larval stage.     

Characteristics of the endocrine system in Drosophila melanogaster 1 (2)gl mutants, differing in time of death]

A comparative study of the state of the endocrine system and one of the larval organs, the salivary gland, has been carried out in larvae homozygous for the 1(2)gl gene. They differ in time of death (death at the third larval instar--larval allele, and at the prepupal state--prepupal allele). It is shown that homozygotes for the larval and prepupal allele have underdeveloped prothoracal glands. Corpora allata in homozygotes for the larval allele does not differ from the norm. Corpora allata in homozygotes for the prepupal allele is decreased proportionally to the decrease of prothoracal glands. A decrease of gland size is due to a decrease of the volume of cell but not to their number; this decrease is accompanied by the decrease of their relative DNA content. Salivary glands in homozygotes are reduced and comprise 80% of the normal size in homozygotes for the prepupal allele and 50% for homozygotes for the larval allele. Polyteny level in the salivary gland nuclei is much decreased as compared with the normal level. DNA level is more reduced in larvae homozygous for the larval allele.     

The properties of hybrids formed between the P-group plasmid RP1 and various plasmids from Pseudomonas aeruginosa

Summary Ribosomal DNA content has been determined in several adult and larval tissues of Drosophila melanogaster. Underreplication of rRNA genes was observed in polytenic salivary glands of larvae. On the contrary, polytenic/polyploid ovaries showed no decrease in rDNA. It is concluded that polyteny is not necessarily associated with underreplication of rDNA. No other tissue examined displayed any change in rDNa redundancy. Third-instar-larvae showed a decrease in rDNA amount which might be partly accounted for by underreplication of rDNA in salivary glands. No such decrease was seen in pupae. Bobbed genotypes were essentially similar to wild type in all tissues except salivary glands. In this case, it was found that the extent of underreplication is less in bobbed as compared to wild genotypes.Ribosomal DNA activity was examined in various tissues of Drosophila melanogaster. The rates of rRNA synthesis vary greatly between various tissues. It is concluded that a control at the level of gene activity operates as differences in the amount of precursor rRNA synthesized can be observed both in flies of varying rDNA contents as well as in various tissues of the same genotype.     

Photoinduced bonding of endogenous ecdysterone to salivary gland chromosomes of Chironomus tentans

Endogenous ecdysterone has been bonded to chromosomal loci by irradiation of Ch. tentans salivary glands. The hormone has been localized on the polytene chromosomes by indirect immunofluorescence microscopy. Hormone binding to chromosomes is stage-specific. Seven chromosomal loci could be identified which specifically bound hormone in larval salivary glands, and 21 chromosomal loci which specifically bound hormone in prepupal salivary glands. All puffs that have been described by Clever (1961) as being inducible by ecdysterone have been found to contain irreversibly bound ecdysterone in prepupal salivary gland chromosomes. A small number of puff sites in larval salivary gland chromosomes exhibited varying amounts of bound ecdysterone, (as judged by fluorescence intensity) most notably 117B and Balbiani rings 1 and 3 on chromosome IV. In addition to stage specific binding sites, there were many others showing equal binding of the hormone in both, larval and prepupal, stages of development. — Fluorescence intensities (reflecting the amount of bonded hormone) at puff sites along the tip section of the prepupal salivary gland chromosome arm IR have been computed indicating that differences between fluorescence intensities of different puffs can be expressed as multiples of a basic fluorescence intensity. Thus, the amount of fluorescence intensity (bonded hormone) in the various puffs may be quantized. — The data indicate that in Ch. tentans salivary glands ecdysterone acts, at the chromosomal level. The development of larvae into prepupae generates more puff sites and more hormone binding. This is discussed in the light of current models of hormone-receptor function.     

Anomalous development and differential DNA replication in the X-Chromosome of a Drosophila hybrid

Male hybrids of the cross D. azteca x D. athabasca are larger (hybrid giant males) than their parents, whereas hybrid females are of the same size as the parental species. Microspectrophotometric measurements have shown that the larval polytene salivary gland chromosomes of hybrid giant males undergo one more endoreplication than those of their sisters or parents. Replication patterns of the larval salivary gland chromosomes were compared after pulse labeling with ³H-thymidine and autoradiography. In females of either species as well as of hybrids X-chromosomes and autosomes are equally labeled, i.e. all chromosome arms replicate synchronously. In males, however, often fewer sites are labeled on the X-chromosome than on the autosomes. In addition, in a significant number of nuclei from D. athabasca males and also from hybrid giant males the converse can also be observed: i.e. more sites are labeled on the X-chromosome than on the autosomes. The modified labeling patterns are interpreted as an indication of a time-shift in the replication of hemizygous X-chromosomes in males, in relation to the autosomes.     

Replication in Drosophila chromosomes

Prolongation of larval life in Drosophila melanogaster, by growing wild type larvae at lower temperature, or in animals carrying the X-linked mutation giant is known to result in a greater proportion of nuclei in salivary glands showing the highest level of polyteny. We have examined by autoradiography the patterns of ³H-thymidine incorporation during 10 min or 1 min pulses in salivary gland polytene chromosomes of older giant larvae and of wild type late third instar larvae of D. melanogaster grown since hatching either at 24 ° C or at 10 ° C. The various patterns of labelling and their relative frequencies are generally similar in glands from the warm-(24 ° C) or cold (10 ° C)-reared wild type larvae, except the interband (IB) labelling patterns which are very frequent in the later group but rare in the former. The IB type labelled nuclei in cold-reared wild type larvae show labelling ranging from only a few puffs/interbands labelled to nearly all puffs/interbands labelled. In warm-reared wild type larvae, very low labelled IB patterns are not seen. In older giant larvae, the ³H-thymidine labelling patterns are in most respects similar to those seen in cold-reared wild type larvae. In 1 min pulsed preparations from all larvae, the IB patterns are relatively more frequent than in corresponding 10 min pulsed preparations. No nuclei with the continuous (2C or 3C) type of labelling pattern, with all bands and interbands/puffs labelled, were seen in 1 min pulsed preparations from cold-reared wild type or in giant larvae, and only a few nuclei in 1 min pulsed preparations from warm-reared wild type larvae exhibited the 2C labelling pattern. Analysis of silver grain density on specific late replicating sites in late discontinuous (1D) type labelled nuclei suggests that the rate of DNA synthesis per chromosomal site is not different at the two developmental temperatures. It is suggested that correlated with the prolongation of larval life under cold-rearing conditions or in giant larvae, the polytene replication cycles are also prolonged. It is further suggested that the polytene S-period in these larvae is longer due to a considerable asynchrony in the initiation and termination of replication of different sites during a replication cycle.     

Vacuole dynamics in the salivary glands of Drosophila melanogaster during prepupal development

A central function of the Drosophila salivary glands (SGs), historically known for their polytene chromosomes, is to produce and then release during pupariation the secretory glue used to affix a newly formed puparium to a substrate. This essential event in the life history of Drosophila is regulated by the steroid hormone ecdysone in the late‐larval period. Ecdysone triggers a cascade of sequential gene activation that leads to glue secretion and initiates the developmentally‐regulated programmed cell death (PCD) of the larval salivary glands, which culminates 16 h after puparium formation (APF). We demonstrate here that, even after the larval salivary glands have completed what is perceived to be one of their major biological functions – glue secretion during pupariation – they remain dynamic and physiologically active up until the execution phase of PCD. We have used specific metabolic inhibitors and genetic tools, including mutations or transgenes for shi, Rab5, Rab11, vha55, vha68‐2, vha36‐1, syx1A, syx4, and Vps35 to characterize the dramatic series of cellular changes occurring in the SG cells between pupariation and 7–8 h APF. Early in the prepupal period, they are remarkably active in endocytosis, forming acidic vacuoles. Midway through the prepupal period, there is abundant late endosomal trafficking and vacuole growth, which is followed later by vacuole neutralization and disappearance via membrane consolidation. This work provides new insights into the function of Drosophila SGs during the early‐ to mid‐prepupal period.     

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.     

Sequence of puff formation inRhynchosciara polytene chromosomes

The chief characteristics of the life cycle ofRhynchosciara sp. are: egg stage (12 days); three larval instars of approximately 6 days each, followed by a 4th instar of approximately 40 days duration; pupation (6 days); and adult form (5–6 days). Maps of the 4 polytene chromosomes ofRhynchosciara sp. have been prepared, and the temporal sequence of puff formation on the chromosomes described. The cocoon is synthesized during the prepupal period, and at this time major puffs are seen on all chromosomes. The largest and most numerous puffs occur on the salivary gland chromosomes during the 24 hours prior to the last or prepupal molt. Three of the puffs that occur at this time are DNA-puffs (Summary see p. 249). Research sponsored by the U.S. Atomic Energy Commission under contract with the Union Carbide Corporation.     

DNA synthesis in the giant salivary chromosomes of Drosophila virilis prior to pupation

Both two-wavelength microspectrophotometry of Feulgen-stained whole nuclei and autoradiography of H³-thymidine incorporation by giant salivary chromosomes in Drosophila virilis demonstrate a net decrease in the relative rate of salivary DNA synthesis during the late third instar and prepupal stages of development. Amounts of DNA-Feulgen per nucleus were distributed into several classes, the means of which closely approximated values projected as geometric multiples of the basic somatic DNA level estimated from hemocyte nuclei of the same larvae. Comparison of DNA polytene class frequencies showed no statistical difference between male larvae of different development stages, although female prepupae showed a greater frequency of nuclei in higher polytene classes when compared to male prepupae of the same age. Comparison of chromosomal H³-thymidine incorporation with previously described H³-histidine incorporation suggests that the amino acid labeling, which reaches a maximum during the prepupal period, has a physiological significance distinct from chromosomal endoreplication.     

Sequential gene activation by ecdysone in polytene chromosomes of Drosophila melanogaster. VI. Inhibition by juvenile hormones.

In the salivary gland chromosomes of late-third instar larvae and in late (8- to 12-hr) prepupae of Drosophila melanogaster, there are ecdysone-induced sequences of puffing patterns which can be reproduced in vitro. These two sequences are separated by a period when the glands are thought to be exposed to a low titer of β-ecdysone and during which they acquire the competence to respond to ecdysone at the late prepupal puff sites. Attempts to modify either the late larval or the late prepupal responses to ecdysone in vitro by the simultaneous addition of juvenile hormone (JH) with ecdysone, to larval or prepupal glands, respectively, are unsuccessful. If, however, JH (ca. 10^?6M) is added to larval glands cultured 6 hr in ecdysone and then 3 hr in JH alone, the subsequent induction of prepupal ecdysone puffs is inhibited. Thus the role of JH appears to lie in modifying the acquisition of competence to respond to ecdysone rather than in a direct antagonism between the two hormones.     

Hormonally regulated expression of arginine kinase in Drosophila melanogaster

Summary Arginine kinase (AK) is present throughout the life cycle of Drosophila melanogaster, but there is a sharp, transient peak of AK activity during the prepupal period and a second period of elevated activity at the time of eclosion of the adult. Imaginal discs show the greatest increase in AK activity at the prepupal stage of those tissues assayed. The prepupal peak is not seen when the temperature-sensitive ecdysoneless mutant ecd-1 is shifted to 29° C at mid-third instar larval stage. The peak in activity reappears when ecd-1 is either shifted back to 20° C after 60 h at 29° C or is fed 20-hydroxyecdysone. At the restrictive temperature, imaginal discs from ecd-1 larvae progressively lose AK activity, whereas discs from 20-hydroxyecdysone-fed larvae have a marked increase in AK activity at stage P3 of the prepupal period. These data suggest that the prepupal peak is regulated by the hormone 20-hydroxyecdysone.     

Deoxyribonucleases of the organs of Drosophila hydei at the onset of metamorphosis

The tissue distribution of deoxyribonucleases has been studied in the organs of Drosophila hydei at the onset of metamorphosis. The enzymes were separated by disc electrophoresis and detected directly in the gel. An extensive shift in the wide spectrum of activities that has been observed at metamorphosis indicates that deoxyribonucleases play an important role at this time in development. On the basis of the tissue distribution of these enzymes, it has been possible to assign probable functions to several of the activities. An intense activity appears in the prepupal salivary gland which is not detected in this organ in the larval stage. This observation is of particular interest in view of the changes that have been observed in the chromosomal puffing patterns of the salivary glands just prior to metamorphosis. A class of activities, which is probably of lysosomal origin, is more prevalent in the prepupal tissues. The data suggest that an increased synthesis of lysosomes is a general reaction of most larval tissues at the onset of metamorphosis irrespective of whether a tissue undergoes total histolysis. The larval intestine contains a factor which strongly inhibits Drosophila nucleases that are active at low pH. The major nuclease activities of each tissue have been tentatively characterized. A knowledge of the enzyme properties is expected to facilitate the isolation of DNA from the individual tissues.This work was performed in the Max-Planck-Institut für Biologie, Abteilung Beermann, Tübingen, Germany. The senior author was supported by the Helen Hay Whitney Foundation.     

Differential replication of male and female X-chromosomes in Drosophila

The replication patterns of larval salivary gland chromosomes of D. hydei and D. melanogaster were studied by autoradiography with tritiated thymidine injected in mid third instar larvae. The male X chromosome showed a different replication behavior in comparison to that of the female X chromosome and autosomes. It is concluded that the male X chromosome finishes its replication earlier than the female X chromosome. Moreover, the time needed for a complete replication cycle of individual identical replication units was found to be shorter in the male than in the female X chromosome. Although the whole X chromosomes behave different there were no differences observed in the sequence of the discontinuous labeling patterns of the two types of X chromosome. One autosomal replication unit was observed which showed a different replication behavior in males and females. The possible origin of the differential behavior of the two X chromosomes is discussed in terms of their difference in degree of polyteny.     

Cytological and autoradiographic studies in Sciara coprophila salivary gland chromosomes

Summary Morphological and metabolic changes on the salivary chromosomes of Sciara coprophila were followed during the later half of the fourth larval instar.Cytological maps were prepared for five successive stages from mid-fourth instar to the prepupal stage. These maps, which constitute a revision of those published earlier by Crouse, summarized our cytological findings and were the basis for studies on DNA replication of these chromosomes.Similar to earlier studies in Chironomidae, differences in the puffing pattern were noted between the anterior and the posterior portions of the salivary gland. The most striking difference was noted in region 2B on chromosome III which produces a large puff only in nuclei from the anterior part of the gland. Other autosomal puffs, although present in both parts of the gland, showed constant differences in size.An increase in the number of bands from mid-fourth to late fourth instar was observed. The new bands are all of the light-staining kind.In Sciara the puffed area may include a large number of bands in addition to the bands which originated the puff. The maximal extent of puffs was determined in terms of chromosomal map regions and the number of bands subject to obliteration.In the autoradiographic experiments use was made of H³-thymidine as DNA precursor. The aim of these studies was to detect any asynchronies in the replication time of bands. In fact, marked differences in the relative rates of uptake of H³-thymidine of a number of bands in a certain proportion of chromosomes have been observed, while others showed uniform incorporation. Since these latter were found with higher frequency the period of uniform labeling must comprise a larger part of the replication cycle then the periods of localized labeling. To assess the validity and constancy of the observed patterns of unequal incorporation, a semiquantitative analysis was carried out. It showed that the bands showing localized uptake may be separated into two broad groups. In one of these groups are the centromere regions and certain chromosomal ends, which are presumably heterochromatic. The other group comprises most of the puff sites and bulbs. Since late replication is characteristic of heterochromatin, we assumed that bands of the former group (C) replicate late in the cycle, while puffs and bulbs start replication early, and the period of equal labeling is intermediate. Other intermediate labeling patterns were observed and are described.It is known that in the fourth instar from two to three DNA replications occur in the salivary gland nuclei, the last of which coincides with puffing. Several stages may be distinguished in the puffing process based on morphology and rates of isotope uptake of the puffs. The first sign of puffing is a very high rate of incorporation at puffs. It is maintained throughout this last DNA synthesis period and only declines when all other chromosomal regions have ceased to replicate. A pattern of high and exclusive uptake at the heterochromatic sites (pattern C) was never observed in this replication; instead puffs are the last regions to terminate DNA synthesis.These results are discussed in relation to several current problems, such as, asynchronous DNA replication, the problem of metabolic DNA, and the concept of the heterochromatic state.Submitted in partial fulfillment of the requirements for the degree of Doctor of Philosophy, in the Faculty of Pure Science, Department of Zoology, Columbia University, New York. This work has been supported by U.S. Public Health Training Grant No. 2Tl-GM-216-05; partial support has been received also from Grants GB 42 and G-14043 from the National Science Foundation to Dr. H. V. Crouse.     

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.     

Differential DNA synthesis in homologous regions of hybrid polytenic chromosomes (Anopheles atroparvus x A. labranchiae)

Differential DNA synthesis is demonstrated in asynaptic regions of the polytenic chromosomes of the Anopheles atroparvus x A. labranchiae hybrid. This differential synthesis is present both in homologous segments with different banding patterns and in morphologically identical segments. Each differential synthesis appears to be related to a specific portion of the replication cycle and due to the fact that one of the two homologues requires a shorter period of time for its duplication.