Satellite DNA associated with heterochromatin in Rhynchosciara

The DNA of Rhynchosciara hollaenderi was examined using isopycnic centrifugation in neutral CsCl. Two low density minor bands (collectively termed satellite DNA) were detected in addition to the main band DNA. Main band DNA has a buoyant density of 1.695 g/cm³. The larger of the two minor bands has a buoyant density of 1.680 g/cm³ while the smaller of the two minor bands has a buoyant density of about 1.675 g/cm³. Thermal denaturation studies have confirmed the presence of the two minor classes of DNA.—The satellite and main band DNAs were isolated in relatively pure form and were transcribed in vitro using DNA-dependent RNA polymerase from Escherichia coli. Annealing of the two complementary RNAs (cRNAs) with main band and satellite DNA was examined using filter hybridization techniques.—The chromosomal distribution of the satellite DNA was determined by in situ molecular hybridization of satellite-cRNA with Rhynchosciara salivary gland chromosomes. Satellite-cRNA hybridized with the centromeric heterochromatin of each of the four chromosomes (A, B, C, and X) and with certain densely staining bands in the telomere regions of the A and C chromosomes. Main band-cRNA annealed with many loci scattered throughout the chromosomes including areas containing satellite DNA.     

Banding studies on the polytene chromosomes of Rhynchosciara hollaenderi

C-, Q-, H-, and Ag-banding have been carried out on the polytene chromosomes of Rhynchosciara hollaenderi. The results of these techniques are presented and are correlated with the molecular data which exists for Rhynchosciara polytene chromosomes. By systematic organization of both banding and molecular data, we have attempted to give as complete a picture as possible of the characteristics of the differentially banding regions. This presents an organized method of approaching mechanisms of banding in terms of structural and functional aspects of the intact chromosome. Polytene chromosomes are particularly suited for this type of analysis and with them, both developmental and evolutionary changes can be conveniently utilized for additional insights into the functions of banding regions.     

Developmental puffing patterns in salivary gland chromosomes of Rhynchosciara hollaenderi

An analysis of puff formation and regression has been carried out in 3 morphologically distinct regions of the Rhynchosciara hollaenderi salivary gland during mid-larval through pupal development. Puffing differences among these 3 regions have been found and analysed for both RNA and DNA puffs. The presence of such differences suggests that the gland regions may also be functionally differentiated. — Developmentally specific sequences of puffs have been distinguished and correlated with morphological and physiological events which occur during the development of Rhynchosciara. The DNA puffs as well as the RNA puffs enlarge and regress at predictably specific developmental stages. The presence of particular puffing sequences in the late larval to pupal period has been compared with the occurrence of known changes in the developmental ecdysone titre for Rhynchosciara. Certain aspects of this developmental picture appear to fit the ecdysone-stimulated puffing model for Drosophila, but other aspects indicate that the Drosophila-based model may not be completely applicable to Rhynchosciara.     

Z-DNA immunoreactivity of Drosophila polytene chromosomes : Effects of the fixatives 45% acetic acid and 95% ethanol and of DNase I nicking

Drosophila salivary chromosomes have been isolated at neutral pH and physiological ionic strength. They display only background level binding of antibodies against Z-DNA. Following exposure to the commonly used fixative 45% acetic acid all of the polytene chromosomes, X and autosomes, show a massive increase in anti-Z-DNA antibody binding. The enhancement from background to intense fluorescence occurs whether the chromosomes are stabilised by two orders of magnitude lower concentration of formaldehyde than that used to minimise protein extraction in classical acid squash preparations, or by physiological concentrations of spermine and spermidine. Nicking of acetic acid-treated chromosomes by DNase I dramatically reduces their Z-DNA immunoreactivity. The histones and non-histones extracted by 45% acetic acid from unfixed and formaldehyde-fixed Drosophila chromatin have been analysed. Exposure of isolated salivary chromosomes to the non-protein-extracting fixative 95% ethanol also enhances Z-DNA immunoreactivity. All of these phenomena must be taken into account in the search for the Z-DNA conformation in cells by cytological techniques.     

Chromosome differentiation,hybrid breakdown and the maintenance of a narrow hybrid zone in Caledia

The protein D1 was obtained from nuclei of Drosophila melanogaster embryos and purified by perchloric acid fractionation and preparative gel electrophoresis. In nuclei its amount is approximately 1% of the amount of DNA by weight. D1 is soluble in 5% perchloric acid and extractable from nuclei by solutions of moderate ionic strength (0.35 M NaCl). Amino acid analysis shows that it is rich in both basic (20%) and acidic (27%) aminoacids. In all these properties D1 resembles HMG proteins (high mobility group; Johns et al., 1975) of vertebrates; however, its apparent molecular weight (50,000) is much higher. The distribution of D1 in salivary gland polytene chromosomes was investigated by immunofluorescence. Two levels of fluorescence intensity were observed: 1) Very bright fluorescence at chromosomal positions 81F, 83E, 101F, 102C and 102F; these sites are shown, by double labeling techniques, to coincide with quinacrine bright sites. 2) Medium to low fluorescence at many sites widely distributed throughout all chromosomes. In order to interpret these results and to relate them to the in vivo distribution of D1, we have investigated the pattern of immunofluorescence staining as a function of the methods of chromosome preparation and salivary gland fixation. The immunological specificity of the anti-D1 serum was studied by comparing its reactivity with D. melanogaster and D. virilis chromosome spreads and whole salivary glands, and by using reagents that minimize non-specific antibody interactions. We conclude that Dl is widely distributed throughout cytoplasm and nucleus, present in many chromomeres but most abundant in chromosomal sites that contain the AT-rich satellite DNA of density 1.672. This distribution, together with available evidence about the nucleotide sequences present in this satellite, suggests that D1 binds preferentially to chromatin containing sequences AATAT and/or AATATAT.     

Study of the organization of polytene chromosomes in the nuclei of <Emphasis Type="Italic">Drosophila melanogaster</Emphasis> pseudonurse cells with the use of the DNA library of the <Emphasis Type="Italic">Drosophila orena</Emphasis> chromocenter

The location of the Drosophila orena chromocenter in polytene chromosomes of pseudonurse cells of the D. melanogaster ovaries (the otu11 mutation) and salivary glands has been studied. Numerous sites of location of the D. orena chromocenter DNA have been found throughout the length of D. melanogaster chromosomes. The specific distribution of the binding sites for the DNA probe has made it possible to identify chromosomes and analyze their mutual positions in the three-dimensional space of the nuclei of pseudonurse cells. The mutual positions of chromosomes have been found to vary, the pericentromeric regions of different chromosomes differing from one another in associative ratios.     

The SuUR gene influences the distribution of heterochromatic proteins HP1 and SU(VAR)3–9 on nurse cell polytene chromosomes of Drosophila melanogaster

We have investigated the distribution of three heterochromatic proteins [SUppressor of UnderReplication (SUUR), heterochromatin protein 1 (HP1), and SU(VAR)3–9] in chromosomes of nurse cells (NCs) and have compared the data obtained with the distribution of the same proteins in salivary gland (SG) chromosomes. In NC chromosomes, the SU(VAR)3–9 protein was found in pericentric heterochromatin and at 223 sites on euchromatic arms, while in SG chromosomes, it was mainly restricted to the chromocenter. In NC chromosomes, the HP1 and SUUR proteins bind to 331 and 256 sites, respectively, which are almost twice the number of sites in SG chromosomes. The distribution of the HP1 and SU(VAR)3–9 proteins depends on the SuUR gene. A mutation in this gene results in a dramatic decrease in the amount of SU(VAR)3–9 binding sites in autosomes. In the X chromosome, these sites are relocated in comparison to the SuUR ⁺, and their total number only varies slightly. HP1 binding sites are redistributed in chromosomes of SuUR mutants, and their overall number did not change as considerably as SU(VAR)3–9. These data together point to an interaction of these three proteins in Drosophila NC chromosomes.Electronic Supplementary Material Supplementary material is available for this article at.     

Messenger-like RNA synthesis and DNA chromosomal puffs in the salivary glands of Rhynchosciara americana

RNA synthesis was studied mainly in the proximal sections of Rhynchosciara salivary glands in late fourth instar at two typical periods of development. These are characterized either by the absence or presence of the so-called “DNA puffs” in the salivary gland chromosomes. It was found that simultaneously with the appearance of the DNA puffs there is a great increase in the synthesis of all RNA species. The greatest increase was found to take place in the rate of synthesis of messenger-like RNA. Four main classes of messenger-like RNA were detected, having mobilities corresponding to 33, 23, 16, and 14 S RNA. There is a correlation between the abundance of the 16 S messenger-like RNA and the degree of opening of the B-2 DNA puff. This species might therefore be transcribed from this puff.     

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.     

The rate of DNA replication in the polytene chromosomes of Rhynchosciara angelae

The distribution pattern of 5-bromodeoxyuridine-labelled DNA from salivary glands of Rhynchosciara angelae upon caesium chloride gradient centrifugation was studied with DNA of different molecular weights. This pattern suggests a very low rate of DNA chain growth in polytene chromosomes. The rate of DNA chain growth was found to be 0.025 μm/min at 24 °C. The result was obtained through the development of a mathematical expression which took into account the distribution of the 5-bromodeoxyuridine-labelled DNA in CsCl gradients.DNA pulse-labelled for a short time sediments more slowly in alkaline sucrose gradients than DNA which has been labelled during a prolonged incubation. However, in neutral sucrose gradients the pattern of banding is the same for both DNAs. This indicates a discontinuity in the newly synthesized DNA strand, but not in the template strand. The transition of slow sedimenting to fast sedimenting DNA observed in alkaline sucrose gradients, occurs very slowly, as would be expected for a slow rate of DNA chain growth.The data obtained provided a means of comparing the number of replication points with the rate of DNA chain elongation and the length of S phase in Rhynchosciara.     

Chromosomal proteins of Drosophila melanogaster and an approach for their localisation on polytene chromosomes

Chromosomal proteins have been prepared from embryos of Drosophila melanogaster and separated into histone and nonhistone fractions by a procedure which completely avoids exposure to extremes of pH. These fractions have been characterised by amino acid analysis and gel electrophoresis. Antisera have been prepared against whole chromatin and against the two chromosomal protein fractions. — A new method is described for the preparation of Drosophila salivary chromosomes. This method employs microdissection techniques and completely avoids the use of acid fixatives. Preservation of fine structure in these preparations is comparable to, if not better than, that in classical acid-fixed preparations. Antisera against embryo chromatin and chromosomal protein fractions react with the salivary chromosome preparations. These reactions exhibit selectivity with different chromosomal structures. Evidence is presented suggesting a specific distribution of protein antigens along the chromosome.     

Identification of glycoprotein receptors within the human salivary proteome for the lectin‐like BabA and SabA adhesins of Helicobacter pylori by fluorescence‐based 2‐D bacterial overlay

Because gastric infection by Helicobacter pylori takes place via the oral route, possible interactions of this bacterium with human salivary proteins could occur. By using modified 1‐ and 2‐D bacterial overlay, binding of H. pylori adhesins BabA and SabA to the whole range of salivary proteins was explored. Bound salivary receptor molecules were identified by MALDI‐MS and by comparison to previously established proteome maps of whole and glandular salivas. By use of adhesin‐deficient mutants, binding of H. pylori to MUC7 and gp‐340 could be linked to the SabA and BabA adhesins, respectively, whereas binding to MUC5B was associated with both adhesins. Binding of H. pylori to the proline‐rich glycoprotein was newly detected and assigned to BabA adhesin whereas the SabA adhesin was found to mediate binding to newly detected receptor molecules, including carbonic anhydrase VI, secretory component, heavy chain of secretory IgA1, parotid secretory protein and zinc‐α₂‐glycoprotein. Some of these salivary glycoproteins are known to act as scavenger molecules or are involved in innate immunity whereas others might come to modify the pathogenetic properties of this organism. In general, this 2‐D bacterial overlay technique represents a useful supplement in adhesion studies of bacteria with complex protein mixtures.     

The pattern of polytene chromosome synapsis in Drosophila species and interspecific hybrids

The pairing of polytene chromosomes was investigated in Drosophila melanogaster, Drosophila simulans and their hybrids as well as in species of the D. virilis group and in F₁ hybrids between the species of this group. The study of frequency and extent of asynapsis revealed non-random distribution along chromosome arms both in interspecific hybrids and pure Drosophila species. It is suggested that definite chromosome regions exhibiting high pairing frequency serve as initiation sites of synapsis in salivary gland chromosomes.     

Behavior of polytene chromosomes of rhynchosciara angelae at different stages of larval development

Summary Polytene chromosomes in cells of salivary gland, Malpighian tubules and intestine of Rhynchosciara angelae are very favorable for study. The polytene chromosomes of the salivary gland are among the largest available for cytogenetics work. The ones in Malpighian tubules and in some parts of the intestine are as large and as favorable for cytological studies as the salivary chromosomes of many species of Drosophila.Two additional characteristics of Rhynchosciara make these flies excellent material for studies on the development of polytene chromosomes. 1.It is possible to observe the banding pattern of the polytene chromosomes at many stages of the larval life for at least 30 days before pupation, and 2. since the gregarious larvae develop simultaneously, one can sample the group at any stage desired. Sampling the group every day, it is possible to follow the development of the chromosomes as though one studied a single individual by observing it every day.We have followed in detail the behavior of the bands in two sections of chromosome B and in one section of chromosome C, at different stages of larval development. Some regions of the chromosomes which are represented by typical euchromatic bands at one stage of the larval development may develop in enormous bulbs, and later on may return to the banded stage again.The formation of the bulbs is not uniform in different sections of the same or of different chromosomes. In section 2 of chromosome B a certain locus swells enormously and then develops an enormous bulb, and later returns to the banded stage. At the point where the bulb was formed there is an accumulation of DNA, in amounts probably several times greater than before the bulb formation. In section 3 of chromosome B and section 3 of chromosome C the extra accumulation of DNA preceeds the formation of the bulb and is maintained during and after it. In the bulb formed in section 3 of chromosome C a single band seems to be responsible for the process.As shown by several authors, experimental evidence suggests that a gene is located within a band. The bulb formation in polytene chromosomes may then be morphological evidence of gene activities. This type of bulb formations and of return to the banded stage is a property of many chromosomes bands, during larval development. This type of behavior of many bands in polytene chromosomes is related to the process of nucleolus formation. However, this behavior may be found in almost all (if not in all) bands of the polytene chromosomes. If so, the behavior of the nucleolus organizer region is only a special case of this general process.The accumulation of DNA in different parts of the chromosome in cells of the same or of different tissues may be an argument against the theory of the constancy of the amount of DNA in all cells of a species. The bulb formations is not peculiar to R. angelae but occurs in several other Diptera.     

Satellite DNA probes of Alstroemeria longistaminea (Alstroemeriaceae) paint the heterochromatin and the B chromosome,reveal a G-like banding pattern,and point to a strong structural karyotype conservation

Alstroemeria species present a well-conserved and asymmetric karyotype. The genus is divided into a Chilean clade, rich in heterochromatin, and a Brazilian clade, poor in heterochromatin. We investigated the distribution of the main repetitive sequences in the chromosomes of the Brazilian species A. longistaminea (2n = 16 + 0-6B) aiming to evaluate the role played by these sequences on the structural organization of the karyotype. In situ hybridization of the three most abundant retrotransposons, corresponding to ~ 45% of the genome, was uniformly distributed. Three satellite DNA sequences, representing near half of the whole satellite fraction (1.93% of the genome), were mainly concentrated on the heterochromatin and one of them painted the whole B chromosome. Noteworthy, some satellites were located on euchromatin, either dispersed or concentrated in clusters along the chromosomes, revealing a G-band-like pattern. The two satellites that presented more C-band- and G-band-like labeling were also hybridized in situ in two other Alstroemeria species. They revealed astonishing similar patterns of distribution, indicating an unusually structural karyotype conservation among Brazilian species.

     

Saliva of the graminivorous Theropithecus gelada lacks proline‐rich proteins and tannin‐binding capacity

Gelada baboons are the sole survivors of the genus Theropithecus and the only known graminivorous primates. They developed special adaptations to their diet such as high‐crowned teeth for processing hard and abrasive feed. The fine‐tuning of salivary protein composition might be another key mechanism that is used by species for adapting to the environment and competing with rivals for exploiting new ecological niches. In order to test whether gelada (graminivorous) and hamadryas baboons (omnivorous) differ in their salivary protein composition, we compared whole saliva samples of captive Theropithecus gelada and Papio hamadryas using gel electrophoresis and tannin‐binding assay. We hypothesized that the amount of proline‐rich salivary proteins with tannin‐binding capacity is higher in baboons consuming a feed with high dicot/monocot rations. Dicots produce tannins as a chemical defense system, discouraging animals from eating them. In contrast to dicots, monocots do not synthesize tannins. The presence of tannin‐binding proteins in saliva should effectively inactivate the dicot tannin‐based defense mechanism and increase the dietary breadth and/or the capability to switch between monocots and dicot leaves. The lack of such tannin‐binding proteins in saliva would indicate a narrow dietary spectrum more restricted to monocots. We found T. gelada to completely lack proline‐rich proteins (PRPs) and tannin‐binding capacity similar to a great variety of other grazing mammals. In contrast, P. hamadryas does possess PRPs with tannin‐binding activity. The findings support a growing body of evidence suggesting a high‐level specialization of T. gelada to grass diets. However, it remains unclear, whether loss of salivary tannin‐binding capacity drove the gelada into its narrow feeding niche, or whether this loss is the result of a long process of increased specialization. Thus, from an ecological point of view, T. gelada appears to be more vulnerable to environmental changes than other baboon species owing to its narrow dietary traits. Am. J. Primatol. 71:663–669, 2009. © 2009 Wiley‐Liss, Inc.     

Nucleoprotein methylation in salivary gland chromosomes of Sciara coprophila: Correlation with DNA synthesis

Methylation and ethylation of chromosomal nucleoproteins have been demonstrated in the salivary glands of Sciara coprophila larvae. A difference in grain distribution pattern was observed between chromosomes incubated in ³H-methyl-methionine and ³H-ethyl-ethionine. Like DNA synthesis, methylation could only be demonstrated at certain developmental stages, and during some of these a close correlation was observed between labelling patterns following ³H-methyl-methionine and ³H-thymidine in separated gland pairs. No such correlation was observed with RNA synthesis. Ethylation of chromosomal non-histone protein could not be correlated with nucleic acid biosynthesis. Feeding ethionine during larval development produced similar nucleolar abnormalities to those previously described in rat liver nucleoli.     

The localisation of an Mr 74,000 major chromatin antigen on native salivary chromosomes of Drosophila melanogaster

An antigen making a major contribution to the immune response to Drosophila melanogaster chromatin resides primarily on a nonhistone charge-class family of proteins of Mr 74,000. Immunofluorescence detects this antigen at interbands, puffs and diffuse bands of D. melanogaster salivary chromosomes isolated without exposure to acid fixatives, and on nucleoplasmic ribonucleoprotein droplets. In the electron microscope, gold labelling reveals the binding of monoclonal antibodies specific for the antigen at chromosomal loci generally bearing putative ribonucleoprotein (RNP) particles. However, the locus 3C 11–12 is remarkable in that it bears putative RNP particles but is virtually unlabelled, suggesting protein specificity at different active loci.