Electron microscopical analysis of Drosophila polytene chromosomes

Structural and Functional Dissection of the 5' Region of the Notch Gene in Drosophila melanogaster

Notch is a key factor of a signaling cascade which regulates cell differentiation in all multicellular organisms. Numerous investigations have been directed mainly at studying the mechanism of Notch protein action; however, very little is known about the regulation of activity of the gene itself. Here, we provide the results of targeted 5'-end editing of the Drosophila Notch gene in its native environment and genetic and cytological effects of these changes. Using the Clustered Regularly Interspaced Short Palindromic Repeats/CRISPR associated protein 9 (CRISPR/Cas9) system in combination with homologous recombination, we obtained a founder fly stock in which a 4-kb fragment, including the 5' nontranscribed region, the first exon, and a part of the first intron of Notch, was replaced by an attachment Phage (attP) site. Then, fly lines carrying a set of six deletions within the 5'untranscribed region of the gene were obtained by ΦC31-mediated integration of transgenic constructs. Part of these deletions does not affect gene activity, but their combinations with transgenic construct in the first intron of the gene cause defects in the Notch target tissues. At the polytene chromosome level we defined a DNA segment (~250 bp) in the Notch5'-nontranscribed region which when deleted leads to disappearance of the 3C6/C7 interband and elimination of CTC-Factor (CTCF) and Chromator (CHRIZ) insulator proteins in this region.

Unusual Drosophila virilis stress-puff at 20CD: cytological localization of a heat sensitive locus and some peculiarities of the heat shock response

Using a series of chromosome aberrations a heat shock (hs) inducible site of the Drosophila virilis heat shock puff 20CD has been cytologically localized in the distal 20C subdivision: the hs puff was not observable in chromosome 2 carrying the Df(2)ebTG-52 deficiency; the bands in the proximal 20D subdivision could not autonomously be activated by hs in aberrant chromosomes that have this deficiency or the In(2)ebPC-19 inversion. An electron microscopy (EM) analysis of the successive stages of puff development in the 20CD and 20F regions shows that the 20CD puff is intially formed from the right part of the 20C6-7 band. In the maximally developed puff, the neighboring bands of the 20C and 20D regions are only partially decondensed; they are seen as discrete compact chromatin clumps. Specific differences in the ultrastructural organization and in response to hs have been found between the D. virilis "unusual" 20CD and typical 20F hs puffs.

Molecular and genetic organization of Drosophila melanogaster polytene chromosomes: evidence for two types of interband regions

The 3A and 60E regions of Drosophila melanogaster polytene chromosomes containing inserted copies of the P[1ArB] transposon have been subjected to an electron microscopic (EM) analysis. We show that both inserts led to formation of new bands within the interband regions 3A4/A6 and 60E8-9/E10. This allowed us to clone DNA of these interbands. Their sequences, as well as those of DNA from other four interbands described earlier, have been analyzed. We have found that, with the exception of 60E8-9/E10 interband, all other five regions under study corresponded to 5' or 3' ends of genes. We have further obtained the evidence for 60E8-9/E10 interband to harbor the 'housekeeping' RpL19 gene, which is transcribed in many tissues, including salivary glands. Based upon the genetic heterogeneity of the interbands observed a revised model of polytene chromosome organization is discussed.

Electron micrograph map of the Drosophila melanogaster polytene chromosome 3R divisions 81 through 90

The banding pattern of the proximal half of the polytene salivary gland 3R chromosome of Drosophila melanogaster was studied with thin section electron microscopy. Bands were identified according to Bridges' revised light microscopic map, which contains 330 single and 121 double bands within the regions 81 through 90. We found a total of 447 bands in this region. 97 Bridges' single bands were easily detected in almost all thin sections, while 177 faint bands could be seen only in some micrographs. 56 Bridges' single bands could not be found. 32 Bridges' doublets were made up of two separate bands each in thin sections. The other 89 Bridges' doublets seemed to be either single bands or remained obscure. A total of 20 small new bands, which were not drawn on Bridges' map, were detected.

Cloning and molecular genetic analysis of Drosophila melanogaster interband DNA

Interband DNA of Drosophila melanogaster polytene chromosomes was studied using a novel approach based on the electron microscopic (EM) analysis of chromosome regions carrying DNA fragments of known molecular genetic composition, inserted by P element-mediated transformation. Insertion of such fragments predominantly into interbands makes it possible to clone interband DNA by constructing genomic libraries from transformed strains and probing them with the insert DNA. The transformed strain P[H-sp70:Adh](61C) has insertion in the 61C7-8 interband on the left arm of chromosome 3. This DNA consists of part of the hsp70 gene promoter fused to the coding region of the Adh gene, and is flanked on either side by P element sequences. We constructed a genomic library from DNA of this strain and isolated a clone containing the insert and the interband DNA. Subsequently the genomic library of wild-type strain was probed with a subclone composed of interband DNA only. We have thus isolated a clone containing the entire native interband. 1289 bp of interband DNA was sequenced and found to be AT-rich (53.4%) with numerous regions of overlapping direct and inverted repeats, regulatory sites, and two overlapping open reading frames (ORFs).

Electron microscopical analysis of Drosophila polytene chromosomes. V. Characteristics of structures formed by transposed DNA segments of mobile elements

An electron microscopical (EM) analysis was performed on regions of polytene chromosomes which contained DNA segments of different genetic composition, inserted by P element-mediated transformation into the Drosophila melanogaster genome. In seven of ten regions examined, containing insertions of the hsp28-ry, hsp70-Adh, ryhsp 70-beta-gal genes and of the ry gene tetramer, new bands appeared. Lack of new bands in three other strains is apparently connected with the fusion of the inserted material to preexisting bands. The new bands do not differ morphologically from the usual bands of polytene chromosomes, and their formation is likely due to predominant insertion of DNA segments into interbands. Among the constructs examined, the minimal length of a DNA segment which appears as a new band is about 5 kb; the DNA packing ratio in the new bands varies from 30 to 50. Activation of the inserted genes by heat shock has enabled us to observe the puffing characteristics of new bands. A sequence of some one kb forms a large interband, or micropuff; the puff size is correlated with the length of the genes being activated. If a DNA segment contains a single gene, then its activation causes the decompaction of the whole band; however, when a DNA segment consists of two genes and the promoter element of the activated gene is positioned in the middle of the sequence, the band splits and only part is decompacted and puffed. The DNA packing ratio in the puffs is 1.4-3.5. The subsequent deletion of the hsp70 promoter but retention of 23, 59, and 73 by from the transcription start points leads to failure of puff formation. In all the transformed sites an increase in the total length of the interbands adjacent to the insert as compared with the initial interband was observed. This increase appears to be due to decompaction of the P element DAN flanking the inserted segments. It is shown that a DNA segment, consisting of four tandemly repeated ry gene copies and interspersed by material which includes P DNA, forms a complex of loose chromatin in which, however, four bands can be resolved. We also observed a lengthening of interband regions containing only the P element sequence itself. Insertion of the complete 2.9 kb P element into the large single 10A1-2 bound of the X chromosome (an insertion in the region approximately 10 kb to the right of the v gene) causes splitting of the band into two parts and formation of a new interband.(ABSTRACT TRUNCATED AT 400 WORDS)

Cytogenetic and molecular aspects of position effect variegation in Drosophila melanogaster. II. Peculiarities of morphology and genetic activity of the 2B region in the T(1;2)dorvar7 chromosome in males

The peculiarities of compact blocks appearing as a consequence of position effect variegation were studied in male polytene chromosomes. In T(1;2)dorvar7/Y males the frequency of nuclei with a block in the 2B region was lower at all temperature and the chromosome region involved in compaction was shorter than in T(1;2)dorvar7/FM6 females. The fraction of nuclei with blocks was considerably increased in dorvar7/0 males, especially at 18 degrees C when the viability of these males is sharply reduced. The following features distinguish the blocks in males from those in females: (i) compaction of the 2B region in the males results in genetic inactivation only to a very small extent; (ii) the structure of the blocks in males is diffuse; and (iii) the male blocks still maintain some transcriptional activity as indicated by 3H-uridine incorporation. The temperature-sensitive period of both block formation and genetic inactivation was found to be during the first 3 h of embryonic development.

Chromosome structure in four wild-type polytene tissues of Drosophila melanogaster. The 87A and 87C heat shock loci are induced unequally in the midgut in a manner dependent on growth temperature

A systematic screen of wild-type Drosophila melanogaster larval organs has revealed three tissues besides the salivary gland with suitable polyteny for detailed cytogenetic analysis: the prothoracic gland, hindgut, and middle midgut. Chromosome banding patterns are very similar between tissues, but puffing patterns show considerable differences. In intact nuclei, oblique substructural elements can sometimes be detected in bands from some of the tissues. As a way of exploiting these newly characterized chromosomes, the heat shock puff response in midgut cells has been studied in detail. The puffing pattern is very similar to that in salivary glands, but an unexpected difference is found in the relative activity of the 87A7 and 87C1 loci, which contain the hsp70 genes. When larvae are raised at 16 degrees C, heat shocks ranging from 10 to 60 min induce only a weak midgut puff at 87A7 that is much smaller than that at 87C1, in contrast to other tissues where both are strongly induced. In pulse-labeled nuclei, an approximately five fold difference in transcriptional activity at the two loci is observed. However, when larvae are raised at 25 degrees C, the converse is found: the 87A7 puff is large, and little or no puffing is detectable at 87C1. Thus, in the midgut, heat shock induced puffing at these two loci is inversely modulated by a mechanism dependent on growth temperature.

The 87A7 chromomere. Identification of novel chromatin structures flanking the heat shock locus that may define the boundaries of higher order domains

The chromatin fiber of eukaryotic chromosomes is thought to be organized into a series of discrete domains or loops. To learn more about these large-scale structures, we have examined the sequence and chromatin organization of the DNA segments surrounding the two hsp 70 genes at the Drosophila melanogaster cytogenetic locus 87A7. These studies indicate that this heat shock locus is flanked on both the proximal and distal sides by novel chromatin structures, which we have called, respectively, scs and scs' (specialized chromatin structures). Each structure is defined by two sets of closely spaced nuclease-hypersensitive sites arranged around a central nuclease-resistant segment. Our findings suggest that these two structures define the proximal and distal boundaries of the 87A7 chromomere and, hence, may be one of the first examples of anchor points for the organization of eukaryotic chromosomes into a series of discrete higher order domains. Moreover, these structures may provide focal points both for the decondensation of the chromomere when the hsp 70 genes are induced by heat shock and for the subsequent rewinding and condensation of the chromomere during recovery from heat shock.

Electron microscopical analysis of Drosophila polytene chromosomes. III. Mapping of puffs developing from one band

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.

Electron microscopical analysis of Drosophila polytene chromosomes. II. Development of complex puffs

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.