The capacity of the fourth chromosome of Drosophila melanogaster to establish end-to-end contacts with the other chromosomes in salivary-gland cells

When the fourth chromosome of Drosophila melanogaster is attached, as the result of an induced translocation, to 21A in 2L or 60E in 2R, its tip exhibits a marked capacity to pair end-to-end with the tips of the other chromosomes. In each of the translocations, about 59 per cent of the contacts involving the tip of 4 were with the tip of X. If this pairing preference reflects structural similarity, the tip of 4 is much more like the tip of X than that of any other chromosome. The significance of this phenomenon is discussed with respect to the standard pattern of end-to-end association in the Oregon-R wild-type stock that provided the control preparations. In the 4-2L rearrangement, the interaction of chromosome 4 with the tip of 2L (101E with 21A) led to pronounced puffing in subdivisions 21A and B, as was most strikingly manifested when the distal segments of 2L failed to synapse and the homologue of paternal origin showed a large puff whereas that of maternal origin (not carrying the fourth chromosome) remained unpuffed.This study was supported in part by a Research Grant (GM-10499) from the National Institutes of Health, U.S. Public Health Service.     

Preparation of Drosophila mitotic chromosomes for electron-microscopic studies]

A method of chromosome spreading on microscopic slides was modified for electron microscopy of metaphase chromosomes in Drosophila tissues. The slides covered with an electron transparent film were plasmochemically modified to make them hydrophilic. A piece of fixed tissue was macerated in 60% propionic acid before spreading chromosomes over the slide. The parts of preparation selected under light microscope for electron microscopic examination were cut and peeled of the slide to the top of a water drop. It was shown that the resolution of chromosomal structures was significantly higher than seen under optical microscope, but lower than in serial sections.     

Replication in Drosophila chromosomes

DNA fibre autoradiography of highly polytenized nuclei in salivary glands of Drosophila nasuta larvae reveals two distinct types of active replicons. Type I replicons are longer (mean size=64 m), have a very high rate of fork migration (average rate=0.95 m/min) and generally occur in large arrays often extending over several thousand m. In contrast, the type II replicons are smaller (mean size= 20 m), slow replicating (average rate=0.07 m/min) and occur in short arrays containing only a few closely spaced active replicons. Evidence is presented that type I replicons are active in the early S and type II in the late S. Observations on autoradiographic labelling of partially lysed polytene chromosomes provide evidence for a lack of temporal and spatial agreement in the activation of origin points in homologous regions of the lateral polytene strands; these observations also suggest local variations in levels of polyteny within a chromosome. On the basis of this and other available information on replication in polytene chromosomes the possible roles of the two replicon types in the generation of the different ³H-thymidine labelling patterns of polytene chromosomes are discussed.We take pleasure in dedicating this paper to our inspiring teacher Prof. S.P. Ray Chaudhuri on his completing 75 years of fruitful life     

Replication in Drosophila chromosomes

The temporal order of replication of specific sites in polytene chromosomes from salivary glands and gastric caeca of Drosophila nasuta larvae was compared using ³H-thymidine autoradiography. Labelling of different cytological regions in segments of chromosome 2R (section 47 A to 49 C) and chromosome 3 (section 80 A to 82 C) was examined in detail in nuclei showing late S-period labelling (2 D and 1D types) in both cell types. The different labelling sites (22 on the 2R segment and 38 on the chromosome 3 segment) are cytologically similar in the two cell types. However, there are profound differences in the labelling frequencies of certain sites in polytene nuclei from salivary glands and gastric caeca during the late S-phase. This suggests that even though a comparable number of chromosomal replicating units operates in the two polytene cell types, the temporal order of completion of replication differs.     

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.     

Replication in Drosophila chromosomes

It is widely known that the bulk of the pericentromeric heterochromatin (-heterochromatin) does not replicate during polytenization in Drosophila. However, a recent DNA-Feulgen cytophotometric study (Dennhöfer 1982a) has claimed equal polytenization of all heterochromatin regions. To re-examine this issue, the amount of Hoechst 33258-bright heterochromatin in non-polytene and polytene nuclei in salivary glands and Malpighian tubules of late third instar larvae of D. nasuta has been compared by cytofluorometry. Since the amount of Hoechst 33258-bright heterochromatin is similar in non-polytene and polytene nuclei in spite of the latter having an enormously high euchromatin DNA content, it is concluded that the -heterochromatin does not replicate during polytenization. The present results further indicate that in the polytene nuclei of Malpighian tubules the -heterochromatin remains at the 2C level whereas in salivary gland polytene nuclei it varies between the 2C and 4C levels.I would like to dedicate this paper to the memory of E. Heitz to commemorate 50 years of - and -heterochromatin     

Sex chromosomes and speciation in Drosophila

Two empirical rules suggest that sex chromosomes play a special role in speciation. The first is Haldane's rule - the preferential sterility and inviability of species hybrids of the heterogametic (XY) sex. The second is the disproportionately large effect of the X chromosome in genetic analyses of hybrid sterility. Whereas the causes of Haldane's rule are well established, the causes of the 'large X-effect' have remained controversial. New genetic analyses in Drosophila confirm that the X is a hotspot for hybrid male sterility factors, providing a proximate explanation for the large X-effect. Several other new findings -- on faster X evolution, X chromosome meiotic drive and the regulation of the X chromosome in the male-germline -- provide plausible evolutionary explanations for the large X-effect.     

GFP-tagged balancer chromosomes for Drosophila melanogaster

We constructed green fluorescent protein (GFP)-expressing balancer chromosomes for each of the three major chromosomes of Drosophila melanogaster. Expression of GFP in these chromosomes is driven indirectly by a Kruppel (Kr) promoter, via the yeast GAL4-UAS regulatory system. GFP fluorescence can be seen in embryos as early as the germ band extension stage, and can also be seen in larvae, pupae, and adults. We show the patterns of GFP expression of these balancers and demonstrate the use of the balancers to identify homozygous progeny.     

Tritiated-histidine incorporation into Drosophila salivary chromosomes

An autoradiographic study of H³-histidine incorporation into nonhistone protein of explanted larval salivary gland chromosomes of D. virilis showed patterns of incorporation that were dependent upon the stage of larval development. The sequence of changes in the development of several puffs in a specific chromosomal region was followed using the appearance of pigment in the anterior spiracles as a means of larval staging. H³-histidine incorporation into these puffs in prepupae occurred as the puffs were regressing in size and protein staining. Acid extraction of histone and nucleic acid failed to alter the character of the autographs; presumably a non-histone protein is involved in the H³-histidine incorporation. Other puff sites in the same prepupal chromosomes showed various patterns of isotopic amino acid incorporation indicating that the pattern reported for a specific region may not be true for all puff sites.     

Electron microscopical analysis of Drosophila polytene chromosomes

Data are presented of electron microscopic (EM) analysis of consecutive developmental stages of Drosophila melanogaster complex puffs, formed as a result of simultaneous decondensation of several bands. EM mapping principles proposed by us permitted more exact determination of the banding patterns of 19 regions in which 31 puffs develop. It is shown that 20 of them develop as a result of synchronous decondensation of two bands, 7 of three and 4 of one band. Three cases of two-band puff formation when one or both bands undergo partial decondensation are described. In the 50CF, 62CE, 63F and 71CF regions puffing zones are located closely adjacent to each other but the decondensation of separate band groups occurs at different puff stages (PS). These data are interpreted as activation of independently regulated DNA sequences. The decondensation of two or three adjacent bands during formation of the majority of the puffs occurs simultaneously in the very first stages of their development. It demonstrates synchronous activation of the material of several bands presumably affected by a common inductor. Bands adjacent to puffing centres also lose their clarity as the puff develops, probably due to "passive" decondensation connected with puff growth. The morphological data obtained suggest a complex genetic organisation of many puffs.     

Three-dimensional light microscopy of diploid Drosophila chromosomes

Fluorescence microscopy, uniquely, provides the ability to examine specific components within intact, even living, cells. Unfortunately, high-resolution conventional fluorescence microscopy is intrinsically a two-dimensional technique and performs poorly with specimens thicker than about 0.5 micron. Probing the spatial organization of components within cells has required the development of new methods optimized for three-dimensional data collection, processing, display, and interpretation. Our interest in understanding the relationship between chromosome structure and function has led us to develop the necessary methodology for exploring cell structures in three dimensions. It is now possible to determine directly the three-dimensional spatial organization of diploid chromosomes within intact nuclei throughout most of the mitotic the cell cycle.     

Electron microscopical analysis of Drosophila polytene chromosomes

Replication studies on prophasic human Y chromosomes reveal 4 early replicating segments in the euchromatic portion. The distal segment of Yp replicates first. After replication of the euchromatic part is almost finished 3 to 5 segments start replication in the heterochromatic portion of Yq. These segments exhibit considerable intraindividual variation with respect to the origin of onset of replication. While the location of these bands — once they are differentiated — is fixed within one individual, the number of these bands varies interindividually.Dedicated to Professor Dr. Ulrich Wolf on the occasion of his 50the birthday     

Electron microscopical analysis of Drosophila polytene chromosomes

Mapping of 16 regions of polytene chromosomes in which 18 one-band puffs develop was carried out with the use of electron microscopy (EM). In most cases a uniform decondensation of the whole band was observed. However, there were examples in which only a part of the band was activated (three puffs) or its right and left parts decondensed simultaneously (three puffs). Splitting of the band into two parts with their further decondensation was also found (one puff). This suggests structural and functional complexity of the bands. On the basis of the data obtained here and those published earlier, a classification of 52 puffs by the number of bands participating in their formation is given. Four classes numbering 22, 21, 7, 2 puffs, developing from 1, 2, 3 and 4 bands, respectively, are revealed. The data show that active chromosome regions are rather diverse in both the pattern of decondensation and expansion of the decondensed region, thus providing evidence of the informational complexity of the majority of active regions.     

Hoechst 33258 fluorescent staining of Drosophila chromosomes

Metaphase chromosomes of D. melanogaster, D. virilis and D. eopydei were sequentilly stained with quinacrine, 33258 Hoechst and Giemsa and photographed after each step. Hoechst stained chromosomes fluoresced much brighter and with different banding patterns than quinacrine stained ones. In contrast to mammalian chromosomes, Drosophia's quinacrine and Hoechst bright bands are all in centric heterochromatin and the banding patterns seem more taxonomically divergent than external morphological characteristics. Hoechst stained D. melanogaster chromosomes show unprecedented longitudinal differentiation by the heterochromatic regions; each arm of each autosome can be unambiguously identified and the Y shows eleven bright bands. The Hoechst stained Y can also be identified in polytene chromocenters. Centric alpha heterochromatin of each D. virilis autosome is composed of two blocks which can be differtiated by a combination of quinacrine and Hoechst staining. The distal block is always Q-H- while the proximal block is, for the various autosomes, either Q-H-, Q+H- or Q+H+. With these permutations of Hoechst and quinacrine staining, D. virilis autosomes can be unambiguously distinguished. The X and two autosomes have H+ heterochromatin which can easily be seen in polytene and interphase nuclei where it seems to aggregate and exclude H- heterochromatin. This affinity of fluorochrome similar heterochromatin was been seen in colcemide induced multiple somatic non-disjunctions where H+ chromosomes were distributed to one rosette and H- chromosomes were distributed to another. Knowing the base composition and base sequences of Drosophila satellites, we conclude that AT richness may be necessary but is certainly an insufficient requirement for quinacrine bright chromatin while GC richness may be a sufficient requirement for the absence of quinacrine or Hoechst brightness. Condensed euchromatin is almost as bright as Q+ heterochromatin. While chromatin condensation has little effect on Hoechst staining, it appears to be "the most important factor responsible for quinacrine brightness.' All existing data from D. virilis indicate that each fluorochrome distinct block of alpha heterochromatin may contain a single a single DNA molecule which is one heptanucleotide repeated two million times.