Das Puffmuster der Borstenapparat-Chromosomen vonSarcophaga barbata

The chromosome complement ofSarcophaga barbata polytene scutellar trichogen and tormogen cells is described and the puffing sequences of chromosome IV were analysed from day 5 to day 17 of pupariation, i. e. from the beginning up to the end of bristle and socket formation at 21°C. There are 5 normal polytene chromosomes and a complex of fibrillar and granular heterochromatin in the giant cell nuclei. It is supposed that the heterochromatic masses represent the underreplicaetd sex-chromosomes. During a 13 day period of development 105 puffs appear in the trichogen cell chromosome IV respective 102 puffs in the tormogen cell chromosome IV. The puffing patterns of these two sister cells show many similarities. However, according to the differences in development, morphology and function of bristle and socket, there are also specific differences in the puffing patterns of the trichogen and tormogen cell. Preliminary observation suggest that the hormone bursicon induces some new puffs in the tormogen cell chromosomes of freshly emerged adults.     

Patterns of puffing activity in the salivary gland chromosomes of Drosophila

A technique for the short term organ culture of larval salivary glands of D. melanogaster is described. Cultured Puff Stage 1 glands respond to 20-OH ecdysone by initiating the cycle of puffing activity characteristic of late larval development and puparium formation. This puffing cycle involves the sequential activation of at least 125 puffs. Their response to ecdysone allows these puffs to be divided into 3 main classes: a) PS1 puffs that regress (e.g. 25AC); b) puffs activated very rapidly (within 5 min) (e.g. 23E, 74EF, 75B) and c) puffs activated only after longer periods (>4 h) (e.g. 62E, 78D, 22C, 63E and 82F). The detailed behaviour of representatives of each class is described. These data support Clever's distinction of ‘early’ and ‘late’ ecdysone responsive sites.     

Rapidly labeled proteins on the salivary gland chromosomes of Drosophila melanogaster

Experiments on short-term and pulse-chase labeling of chromosome proteins of the salivary glands of Drosophila melanogaster show unique patterns of label in the vicinity of chromosome puffs. A high turnover rate is indicated for these nonhistone proteins, which appear to form a fibrous sheath around the chromosomes. Acrylamide gel analyses of the chromosomal proteins that are quickly labeled, comparing compositions at different stages of development with compositions after heat shock, show that all are different and dependent on which chromosomal puffs are active and producing messenger RNA. The necessity for a continuous and rapid interchange of protein between the nucleus and cytoplasm is indicated, and it appears that regulation of gene activity must be related to this dynamic state of protein exchange. From the technical standpoint, it has been found that scanning electron microscopy (SEM) is especially useful for observing silver grains on opaque autoradiographs. It appears also that SEM will prove useful in a variety of studies of chromosome structure.     

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.     

Chromosomal control of foot pad development in Sarcophaga bullata

The puffing schedule of 71 puffs of chromosome B in Sarcophaga bullata polytene foot pad cells were analyzed during an 8 day period of pupal development. The number of puffs fluctuates, with maxima at about day 7 and day 10. The nucleolar volume reaches two maxima which precede the maxima in the number of puffs by approximately one day. With respect to qualitative changes in the puffing pattern, the present study shows that all puffs appear and disappear in a sequential fashion which is related to development. The pattern of potentially active loci and the sequence in which they form puffs are identical in all foot pad cells. Nevertheless, two neighboring cells may differ characteristically in the timing of the activity of a few individual loci relative to the rest of the puffing sequence. Furthermore, pulvilli cells from different pairs of legs may differ in the timing of the entire puffing sequence. It is concluded that puffing, at least in part, is under the control of intracellular processes rather than of external factors such as hormones.     

N-banding in polytene chromosomes of Chironomus and Drosophila

The N-banding patterns of the polytene chromosomes of Drosophila melanogaster, Chironomus melanotus, Ch. th. thummi and Ch. th. thummi x Ch. th. piger were studied. In Chironomus the polytene N-banding patterns correspond to the polytene puffing patterns. This is revealed by comparison of the puffing and N-banding patterns of identical chromosomes. Size and staining intensity of the N-bands reflect the size of the puffs as shown by puff induction. There is no evidence that the N-bands are also located in Chironomus heterochromatin or are restricted to the nucleolar organizer regions. In Drosophila the -heterochromatin is strongly N-positive, whereas the -heterochromatin, as well as the Chironomus heterochromatin is not N-banded. Contrary to Chironomus, the puffs in Drosophila polytene chromosomes do not give rise selectively to well stained N-bands. — The N-banding method is interpreted to stain specifically non-histone protein which is (1) accumulated in genetically active chromosome regions and (2) present in a specific type of heterochromatin (-heterochromatin of Drosophila).     

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.     

Patterns of puffing activity in the salivary gland chromosomes of Drosophila

Exposure of Drosophila melanogaster larvae to high temperature for short periods of time results in marked changes in the puffing patterns of salivary gland chromosomes. Temperature shock induces puffing at 9 specific loci; this pattern of induced puffs shows little developmental specificity and is similar in three strains of D. melanogaster (including the mutant lethal giant-larvae) and in D. simulans. Temperature shock also (i) retards the regression of some developmentally specific puffs and (ii) results in the regression of all other puffs normal to development. The effect of temperature treatment is similar in vivo and after in vitro treatment of salivary glands. The in vitro response is not sensitive to cycloheximide. A similar pattern of induced puffs to that found after temperature treatment is found during recovery of larvae from anoxia, but additional puffs are induced after anoxia. The size and duration of activity of the induced puffs is dependent upon the magnitude of the treatment.     

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.     

Developmental changes in genome activity in Drosophila lebanonensis casteeli pipkin

Puparium formation in Drosophila lebanonensis casteeli is obviously restricted to a certain phase in circadian oscillation. The question whether or not the release of molting hormone is the actual process which is controlled by the circadian oscillation could be approached by using molting hormone-specific changes in genome activity as indication for changes in hormone titer. The identification of hormone specific changes in the puffing pattern of polytene chromosomes should provide a basis for this study.—To this end, a chromosome map of the 7 polytene chromosome arms (1 acrocentric and 3 metacentric chromosomes) of the species was made. Changes in the puffing pattern associated with puparium formation are described and compared with those occurring in response to experimental administration of -ecdysone.—89 puffs were regularly observed in midthird instar larvae. Prior to puparium formation 5 new puffs arise, one at an early stage and 4 attaining their maximum size immediately before puparium formation. Concomitantly, 5 puffs increase considerably in size. These changes in the puffing pattern can be reproduced by injection of ecdysone.—Upon injection of the hormone a clear differentiation between fast reacting loci (within 30–60 min) and slow reacting loci (after 3–4 hours) can be found. As in other Drosophila species the immediate response (within 30–60 min) comprises more than one (5) locus.In memory of Professor Dr. J. Schultz.     

Sex chromosome composition revealed in Characidium fishes (Characiformes: Crenuchidae) by molecular cytogenetic methods

The W chromosome of the fishes Characidium cf. fasciatum, Characidium sp. and Characidium cf. gomesi is heterochromatic, as is usually seen in most Characidium species. Samples of W-chromatin were collected by mechanical microdissection and amplified by DOP-PCR (degenerate oligonucleotide-primed polymerase chain reaction), to be used as painting probes (DCg and CgW) and for sequence analysis. FISH (fluorescence in situ hybridization) with DCg probe painted the whole W chromosome, the pericentromeric region of Z chromosomes and the terminal region of B chromosomes. DOP-PCR-generated fragments were cloned, sequenced and tested by in situ hybridization, but only CgW4 produced positive hybridization signals. Clone sequence analysis recovered seven distinct sequences, of which six did not reveal any similarity to other known sequences in the GenBank or GIRI databases. Only CgW9 clone sequence was recognized as probably derived from a Helitron-transposon similar to that found in the genome of the zebrafish Danio rerio. Our results show that the composition of Characidium’s W chromosome does seem rich in repetitive sequences as well as other W chromosomes found in several species with a ZW sex-determining mechanism.     

Die experimentelle Beeinflussung des Puffmusters von Riesenchromosomen

By treating larvae and prepupae of Ch. thummi with 2 mg/ml oxytetracycline (OTC) about 30 puffs not present in normal development are induced in the salivary gland chromosomes. Already existing puffs become enlarged (cf. Fig. 4). A considerable number of induced puffs appeared in heterozygous condition (cf. Fig. 1a-c). The species Ch. strenzkei does not react in any way to the same treatment. Other inhibitors of protein synthesis such as cycloheximide and chloramphenicole do not influence the puffing pattern in both species. — Animals which had been treated with OTC for 2 hrs show the first signs of puffing. Fully developed OTC-induced puffs are detectable 20 hrs after treatment. At this time the Balbiani rings and the nucleolus are mostly regressed. — Both the induced puffing pattern and the number of heterozygous puffs depend on the genetic constitution of the animals. Animals derived from different locations can be shown to possess different specific spectra of induced puffs. The induced puffing pattern of animals bred from single egg masses is reduced, and heterozygous puffs are rare or absent. — OTC-induced puffs show a strong uptake of tritiated uridine (cf. Fig. 2). Heterozygous puffs are labelled only in the puffed half of the band (cf. Fig. 3).     

Modeling of Dark Puffs Using P Transposons in Polytene Chromosomes of Drosophila melanogaster

Modeling of morphologically unusual dark puffs was conducted using Drosophila melanogaster strains transformed by construct P[ry; Prat:bw], in which gene brown is controlled by the promoter of the housekeeping gene Prat. In polytene chromosomes, insertions of this type were shown to form structures that are morphologically similar to small puffs. By contrast, the Broad-Complex (Br-C) locus, which normally produce a dark puff in the 2B region of the X chromosome, forms a typical light-colored puff when transferred to the 99B region of chromosome 3R using P[hs-BRC-z1]. A comparison of transposon-induced puffs with those appearing during normal development indicates that these puff types are formed via two different mechanisms. One mechanism involves decompaction of weakly transcribed bands and is characteristic of small puffs. The other mechanism is associated with contacts between bands adjacent to the puffing zone, which leads to mixing of inactive condensed and actively transcribed decondensed material and forming of large dark puffs.     

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.     

Chromosome banding in Amphibia

The mitotic and meiotic chromosomes of the marsupial frog Gastrotheca riobambae were analysed with various banding techniques. The karyotype of this species is distinguished by considerable amounts of constitutive heterochromatin and unusual, heteromorphic XY sex chromosomes. The Y chromosome is considerably larger than the X chromosome and almost completely heterochromatic. The analysis of the banding patterns obtained with GC- and AT-base-pair-specific fluorochromes shows that the constitutive heterochromatin in the Y chromosome consists of at least three different structural categories. The only nucleolus organizer region (NOR) of the karyotype is localized in the short arm of the X chromosome. This causes a sex-specific difference in the number of NOR: female animals have two NORs in diploid cells, male animals one. No cytological indications were found for the inactivation of one of the two X chromosomes in the female cells. In male meiosis, the heteromorphic sex chromosomes form a characteristic sex-bivalent by pairing their telomeres in an end-to-end arrangement. The significance of the XY/XX sex chromosomes of G. riobambae for the study of X-linked genes in Amphibia, the evolution of sex chromosomes and their specific DNA sequences, and the significance of the meiotic process of sex chromosomes are discussed.     

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     

Patterns of puffing activity in the salivary gland chromosomes of Drosophila

Salivary gland X chromosome puffing patterns are described for the Oregon stock of Drosophila melanogaster and for the Berkeley stock of D. simulans. In D. melanogaster regular phase specific puffing was recorded at 21 loci in the third larval instar and subsequent prepupal stage. A comparison of the X chromosome puffing patterns of male and female larvae failed to show any qualitative differences although in the males a group of puffs were active for a longer time during development than in females. The X chromosome puffing patterns of D. simulans are similar to those described for D. melanogaster although two puffs (4F 1–4 and 7B 1–3) were active in D. simulans but not in D. melanogaster. The sex differences in puffing observed in D. melanogaster were also observed in D. simulans.