Distribution of RNA polymerase on Drosophila polytene chromosomes as studied by indirect immunofluorescence

Using indirect immunofluorescence visualization techniques we investigated the in situ distribution of RNA polymerase B on Drosophila melanogaster polytene chromosomes. The enzyme was found at many sites distributed throughout the genome in a pattern clearly distinct from that observed for histone H1, but it was especially concentrated in puffs induced by heat shock.     

RNA Polymerase B (or II) in heat induced puffs of Drosophila polytene chromosomes

Using indirect immunofluorescence visualization techniques we investigated the distribution of RNA polymerase B (or II) and histone H1 at heat shock puff loci in Drosophila melanogaster polytene chromosomes at different times during and after heat shock. After heat treatments of from 5 to 45 min, the heat shock puff displayed intense fluorescence when stained for RNA polymerase B, but relatively little fluorescence when stained for histone H1. Returning heat shocked larvae to room temperature resulted in the appearance of a distinctive pattern of RNA polymerase-associated fluorescence in the heat shock puff at 87C, presumably reflecting events associated with the inactivation and regression of this puff. Large differences observed in the apparent RNA polymerase B content of puffs of similar size suggest that the interaction of RNA polymerase B with chromosomal loci does not depend on simply the state of condensation or decondensation of the chromatin.     

Immunoelectron microscopic localization of RNA polymerase B on isolated polytene chromosomes of Chironomus tentans

RNA polymerase B (or II) was localized by immunoelectron microscopy in ultrathin sections of polytene chromosomes isolated from larval salivary glands of Chironomus tentans. The enzyme was found at decondensed sites (puffs and interbands), whereas no detectable RNA polymerase B was present in condensed loci (bands). Within each of the large puffs the highest enzyme concentration was observed wherever the chromatin was in the most decondensed state. Otherwise the enzyme appeared homogeneously distributed within puffs and interbands. This immunoelectron microscopic study, along with the recently published immunofluorescent and autoradiographic analysis of isolated Chironomus chromosomes (Sass, 1982) unequivocally demonstrates that RNA polymerase B is present in most, if not all interbands.     

Localization of sequences coding for histone messenger RNA in the chromosomes of Drosophila melanogaster

In situ hybridization of sea urchin (Psammechinus miliaris, Lytechinus pictus and Strongylocentrotus purpuratus) histone messenger RNA has been used to map complementary sequences on polytene chromosomes from Drosophila melanogaster. The sea urchin RNA hybridizes to the polytene regions from 39D3 through 39E1-2, including both of these bands (39D2 may also be included). This region is identical to the one which hybridizes most heavily with non-polyadenylated cytoplasmic RNA from D. melanogaster tissues. Sea urchin mRNAs coding for several individual histones each hybridize across the entire region from 39D3 (or D2) through 39E1-2, as would be expected if the individual mRNA sequences are interspersed. In view of the apparently even distribution of sequences complementary to histone mRNA within the 39D3-39E1-2 region, the significance of the several polytene bands in this region remains an open question. Biochemical characterization of the hybrids between sea urchin histone mRNA and D. melanogaster DNA suggests that sea urchin mRNAs for several of the histone classes have some portions which retain enough sequence homology with the D. melanogaster sequences to form hybrids, although the hybrids have base pair mismatches. In situ hybridization of chromosomes in which region 39D-E is ectopically paired show no evidence of sequence homology in the chromosome region with which 39D-E is associated.     

Monoclonal antibody directed against RNA polymerase II of Drosophila melanogaster

Summary Monoclonal antibodies were raised against purified RNA polymerase II (or B) from Drosophila melanogaster. The antibody produced by one hybridoma cell clone was found to be directed against the two large subunits of the enzyme. The absence of antibodies directed against proteins possibly contaminating the antigens used for immunization allowed us to identify RNA polymerase unequivocally in interbands and puffs of polytene chromosomes. Within a single heat shock puff (87C1) RNA polymerase was found to be clustered in two separate areas suggesting two distint regions of RNA polymerase activity in this puff.Abbreviations FITC fluorescein isothiocyanate - PAGE polyacrylamide gel electrophoresis - PBS phosphate buffered saline - SDS sodium dodecyl sulfate - Enzyme DNA-dependent RNA polymerase or nucleotide-triphosphate - RNA nucleotidyltransferase (EC 2.7.7.6)     

A comparison of bacterial RNA-polymerase RNA synthesis on polytene Drosophila chromosomes with transcription in living cells

The incorporation of 3H-uridine in different regions of polytene chromosomes in live cells of the Drosophila melanogaster salivary glands was compared with the incorporation of 3H-UTP in the same regions under the incubation of cytological preparations of these chromosomes with the E. coli RNA polymerase. The label distribution by regions was compared with the DNA content in them. Individual regions of chromosomes differ by 3H-uridine incorporation in live cells to a much greater extent than by 3H-UTP incorporation in vitro under the incubation with a non-homologous enzyme. RNA synthesis in an exogenous enzyme depends on the DNA content in different chromosome regions to a much greater extent than RNA synthesis in vivo. The correlation of label distribution after 3H-uridine incorporation in live cells and after RNA synthesis in vitro on the preparations by the bacterial RNA polymerase is, correspondingly, very low. This enzyme forms, however, RNA's on puffs 2-3 times more actively than on the same regions in non-puffing state but this difference is dozens of times greater in live cells. RNA synthesis in vitro is, thus, non-specific and does not correspond practically to the intensity of RNA synthesis on the same chromosome regions in live cells. At the same time, as in live cells, the E. coli enzyme synthesizes twice more RNA on the single X-chromosome of males (1X2A) than on each of X-chromosomes of diploid (2X2A) and triploid (3X3A) females or superfemales (3X2A), whereas in intersexes (2X3A) X-chromosomes display intermediate template activity. Thus, RNA synthesis by a heterologous enzyme in vitro does not differ by this index from the synthesis in live cells. It is suggested that differences in the template activity of X-chromosomes in vitro depending on the sex index (X : A) are due to different degree of DNP condensation in these chromosomes. In spite of differences in the degree of condensation, the male X-chromosome binds on the fixed preparation approximately the same amount of thymus histone F1 carrying fluorochrome as each of two female X-chromosomes. Hence, there is no sharp difference between the male and female X-chromosomes by the number and length of DNA regions accessible for interaction with exogenous proteins. On the basis of the data obtained, a hypothesis about two levels and, respectively, two mechanisms of control gene activity in animal chromosomes is considered. The first mechanism is, supposedly, based on decondensation of DNP appears to result in that the same proteins-regulators in the same amount activate corresponding genes in X-chromosome in males twice more strongly than in females.     

The location of 5S RNA genes in lampbrush polytene chromosomes from Drosophila

Drosophila polytene chromosomes were transformed into lampbrush-like structures by exposure to solutions of alkali-urea. In this process, the chromosomes shorten and widen, and the bands (chromomeres) extend laterally into loops leaving a central core between the paired homologues. The expanded polytene chromosomes are very similar in appearance to the true lampbrush chromosomes of amphibian oocytes and to ordinary chromosomes in pachytene. The denaturing effects of alkali-urea were partially counteracted by return of the treated chromosomes to Ringer solution. These observations are interpreted in terms of recent findings on protein backbones in chromosomes, and indicate that chromosomes generally may have very similar basic organization, despite differences due to species, polyteny and degree of condensation. To gain more information on the specific location of a structural gene, ¹²⁵I-labelled low molecular weight (containing 5S RNA) was hybridized in situ to normal and lampbrush-like polytene chromosomes. Autoradiography showed silver grain distribution for 5S RNA consistent with hybridization primarily to the loop regions of the lampbrush chromosomes rather than the core. This provides further indirect evidence that structural genes like 5S RNA may be located on the bands (chromomeres) and not the interbands of normal polytene chromosomes.     

The Chriz–Z4 complex recruits JIL-1 to polytene chromosomes,a requirement for interband-specific phosphorylation of H3S10

The conserved band-interband pattern is thought to reflect the looped-domain organization of insect polytene chromosomes. Previously, we have shown that the chromodomain protein Chriz and the zinc-finger protein Z4 are essentially required for the maintenance of polytene chromosome structure. Here we show that both proteins form a complex that recruits the JIL-1 kinase to polytene chromosomes, enabling local H3S10 phosphorylation of interband nucleosomal histones. Interband targeting domains were identified at the N-terminal regions of Chriz and Z4, and our data suggest partial cooperation of the complex with the BEAF boundary element protein in polytene and diploid cells. Reducing the core component Chriz by RNAi results in destabilization of the complex and a strong reduction of interband-specific histone H3S10 phosphorylation.     

Histone localization in polytene chromosomes by immunofluorescence

Polytene chromosomes of Chironomus thummi were treated with antisera elicited by purified calf thymus histone fractions, and the location of each histone type was visualized by the indirect immunofluorescence technique. Each of the antisera produced specific and distinct patterns of fluorescence, suggesting that it is possible to use the indirect immunofluorescence technique to study the in situ organization of each histone in the various regions of the chromosomes. H1 and H2A antisera produced diffuse fluorescence patterns in acetic acid-fixed chromosomes which become more defined in formaldehyde-fixed preparations. Antisera to H2B, H3 and H4, when reacted with either formaldehyde- or acetic acid-fixed chromosomes, produce distinct banding patterns closely resembling the banding of acetoorcein-stained or phase-contrast-differentiated chromosomal preparations. These antisera produce corresponding patterns of fluorescence for each chromosome, suggesting that the overall organization of the histones is similar in the various bands. Because the dense band regions stain more brightly with antihistone sera than the less compacted interband areas, we believe that the number of antigenic sites of chromosome-bound histones is related to the amount of DNA present, and that the accessibility of histone determinants does not differ between the bands and interbands.     

Activity of the endogenous RNA polymerase on fixed polytene chromosomes.

Fixed polytene chromosomes can serve as templates for RNA synthesis in situ, using the endogenous chromosomal DNA-dependent RNA polymerase. Labelling is mainly localized in band regions. However, radioactivity can also be found in interbands and puffs similar to that which occurs in vivo. It is also found by this technique that the nucleolar RNA polymerase appears to be active in these preparations and requires Mg²⁺ for activity. Since the pattern of the RNA transcribed in situ with the DNA-dependent RNA polymerase from E. coli of native chromosomes differs from that with endogenous RNA polymerase and resembles the one obtained with heat-treated chromosomes, it is suggested that the polymerase from E. coli does not act specifically on eukaryotic chromosomes.     

Transcription of intercalary heterochromatin regions in Drosophila melanogaster cell culture

Labelled RNA preparations (total newly synthesized RNA, as well as stable cytoplasmic RNA) isolated from a cell culture of D. melanogaster were hybridized in situ with polytene chromosomes. Apart from the nucleolus, in all cases the regions adjacent to the chromocentre in the polytene chromosomes and the intercalary heterochromatin regions in the X chromosome and the autosomes are the most intensively labelled. In the case of asynapsis of polytene chromosomes in heterozygotes the label is detected in a number of intercalary heterochromatin sites in one homologue only ("the asymmetrical label"). The same kind of radioactivity distribution in intercalary heterochromatin regions was observed after a hybridization of polytene chromosomes with cloned DNA fragments (Ananiev et al., 1978, 1979) coding for the abundant classes of messenger RNA (Ilyin et al., 1978) in a cultured D. melanogaster cells. In some regions of intercalary heterochromatin which do not contain these fragments the "'asymmetrical" type of label distribution is observed after hybridization with cell RNA. - These results lead one to regard the intercalary heterochromatin regions as "nests" comprising different types of actively transcribable genes, the composition of each nest varying in different stocks of D. melanogaster.     

Elementary structures in polytene chromosomes of Drosophila melanogaster

Whole-mounted polytene chromosomes were isolated from nuclei by microdissection in 60% acetic acid and analyzed by electron microscopy. Elementary chromosome fibers in the interchromomeric regions and individual chromomeres can be distinguished in polytene chromosomes at low levels of polyteny (2⁶–2⁷ chromatids). Elementary fibers in the interbands are oriented parallel to the axis of the polytene chromosome. Their number roughly corresponds to the expected level of polyteny. These fibers have an irregular beaded structure, 100–300 Å in diameter, and there is no apparent lateral association between them in the interchromomeric regions. Most bands, in contrast, form continuous structures crossing the entire width of the chromosome. Polytene chromosomes isolated in 2% or 10% acetic acid can be reversibly dispersed in a solution for chromatin spreading. The spread chromosomes consist of long uniform deoxyribonucleoprotein (DNP) fibers with a nucleosome structure. This supports the notion that continuous DNA molecules extend through the entire length of a polytene chromosome and that the nucleosome structure exists both in bands and interbands. Analysis of the band shape and of the fibrillar pattern in the interbands emphasizes that the polytene chromosome assumes a ribbonlike structure from which the more complex three-dimensional structure of the polytene chromosome at higher levels of polyteny develops.