Differential DNA synthesis in heterochromatic and euchromatic chromosome sets of Planococcus citri

In males of the mealy bug Planococcus citri, Nur (1966) counted five heterochromatic (H) and about 5, 10, 20, 40, or 80 euchromatic (E) chromosomes in testis sheath nuclei which were undergoing endomitosis. He suggested that the H chromosomes were not replicating and that the nuclei were becoming polyploid as a result of successive cycles of replication of only the E chromosomes. This hypothesis was tested using autoradiography with H³-thymidine to detect DNA synthesis and microspectrophotometric measurements of the Feulgen reaction in nuclei to detect quantitative changes in DNA. — The integrated absorbance of the whole nucleus and of the isolated clump of heterochromatic chromosomes (H body) in polyploid testis sheath nuclei were measured using the mechanical scanner of the CYDAC system. The absorbance of the H body was similar in all testis sheath nuclei examined and was not significantly different from the absorbance of a haploid set of H chromosomes measured after meiosis. The absorbance of the euchromatic component varied in different sheath nuclei, the values closely corresponding to the terms of the series 2c, 4c, 8c. This series is expected if the DNA in the E chromosomes is exactly doubled at each cycle of replication. — Autoradiographs showed that most labeled sheath nuclei had silver grains localized exclusively over euchromatin. With one exception, the remainder of the labeled nuclei had silver grains over both euchromatin and the H body. The observation that euchromatin was much more heavily labeled than the H body and that labeled H bodies occurred at a low frequency and only in the presence of labeled euchromatin suggests that the H body did not incorporate the label and that the silver grains over the H body were the result of -particles which originated in proximal euchromatin.     

Structure and DNA methylation pattern of partially heterochromatinised endosperm nuclei in Gagea lutea (Liliaceae)

Pentaploid endosperm nuclei in certain Gagea species exhibit large masses of sticky and dense chromatin, not observed in somatic nuclei. These heterochromatin masses most probably stem from the triploid chalasal polar nucleus of the embryo sac, thus representing an example of facultative heterochromatinisation in plants. In the present investigation, we studied the nuclei in Gagea lutea (L.) Ker-Gawl. endosperm tissue. The position of the heterochromatin in interphase nuclei was observed by confocal laser scanning microscopy (CLSM) and the DNA methylation status of the euchromatin and heterochromatin was analysed by immunolabelling with an antibody raised against 5-methylcytosine (anti-5-mC). In young endosperms, heterochromatin was relatively dispersed, occupying some peripheral and inner parts of the nuclei. In a later endosperm development, the nuclei became smaller and more pycnotic, and the heterochromatin masses were placed predominantly near the nuclear periphery. The distribution of anti-5-mC labelling on the heterochromatic regions was unequal: some parts appeared hypermethylated while other parts were, like the euchromatin, not labelled. During mitosis, the labelling intensity of all the chromosomes was approximately the same, thus indicating that there are no cytologically detectable methylation differences among the individual sets of chromosomes. However, differences in the anti-5-mC signal intensity along individual chromosomes were observed, resulting in banding patterns with highly positive bands apparently representing constitutive heterochromatic regions. From these results it is obvious that facultative heterochromatinisation, in contrast to constitutive heterochromatinisation, need not be strictly accompanied by a prominent DNA hypermethylation. Received: 24 April 1997 / Accepted: 28 July 1997     

Restriction enzyme digestion of heterochromatin inDrosophila nasuta

In situ digestion of metaphase and polytene chromosomes and of interphase nuclei in different cell types ofDrosophila nasuta with restriction enzymes revealed that enzymes like AluI, EcoRI, HaeIII, Sau3a and SinI did not affect Giemsa-stainability of heterochromatin while that of euchromatin was significantly reduced; TaqI and SalI digested both heterochromatin and euchromatin in mitotic chromosomes. Digestion of genomic DNA with AluI, EcoRI, HaeIII, Sau3a and KpnI left a 23 kb DNA band undigested in agarose gels while withTaqI, no such undigested band was seen. TheAluI resistant 23 kb DNA hybridized insitu specifically with the heterochromatic chromocentre. It appears that the digestibility of heterochromatin region in genome ofDrosophila nasuta with the tested restriction enzymes is dependent on the availability of their recognition sites.     

Studies in heterochromatin DNA: accessibility of late replicating heterochromatin DNA in chromatin to micrococcal nuclease digestion

Heterochromatin DNA in cactus mouse (Peromyscus eremicus) replicates in the late S phase of cell cycle. A method of obtaining cells which contain DNA preferentially labeled at heterochromatic areas by a pulse-labeling of late replicating DNA is described. When the nuclei of P. eremicus cells containing radioactively labeled DNA in heterochromatin were digested with micrococcal nuclease and the resultant nucleosomal DNA was separated by gel electrophoresis, it was found that the repeat length of nucleosomal DNA in the heterochromatin DNA is not different from that of the bulk of the genomic DNA. Furthermore, there was no significant difference in the accessibility to digestion by micrococcal nuclease between the late replicating heterochromatin DNA and the total DNA under our digestion conditions. Two dimensional gel electrophoresis patterns of nucleosomal DNAs isolated from micrococcal nuclease digested nuclei from P. eremicus, P. collatus, and P. crinitus cells in culture were very similar. Cytogenetic data showed that these three species are different in heterochromatin but similar in euchromatin.     

Chromatin and histones in mealy bug cell explants: activation and decondensation of facultative heterochromatin by a synthetic polyanion

In spermatogonial cells of the mealy bug, Planococcus citri, at interphase the five maternal chromosomes appear as diffuse euchromatin and the five paternal chromosomes are heterochromatic, genetically inactive, and incorporate tritiated uridine into RNA at a diminished rate. Testes squashes were treated with 2–10 mg/ml of the polyanion, polystyrene sulfonate (PSS). The gonial cell nuclei decondensed and after 15 minutes they became uniformly granular and similar in appearance to wholly euchromatic nuclei. When testis expiants were incubated with PSS (2–10 mg/ml) for from 15 to 120 minutes, all stages of deheterochromatization were recovered. The Feulgen reaction revealed that the uniform granules contained DNA; methyl-green-thionin staining indicated that the nucleolus contained RNA. When tritiated uridine was added after 15 minutes of PSS and then incubation continued, autoradiography revealed incorporation into euchromatin and decondensing heterochromatin. Incorporation of uridine increased with dosage of PSS up to 4 mg/ml. PSS (20 mg/ml) was toxic to the cells: They incorporated no uridine and were badly damaged. RNAase treated controls were also devoid of label.—PSS treated cells showed a negative alkaline-fast-green reaction for histone. In vitro a complex was formed between calf thymus histone and PSS which was soluble only above pH 8.5, but not separable on a Dowex acetate ion exchange column. These findings suggest that, probably by disrupting the structure of the DNA-histone complex, polystyrene sulfonate brings about structural decondensation of heterochromatin and enables it (and euchromatin) to incorporate tritiated uridine into RNA at an increased rate.     

EM autoradiographic studies on polytene nuclei of Drosophila melanogaster

Replication in the chromocentre heterochromatin of salivary gland polytene nuclei of Drosophila melanogaster has been examined by ³H-thymidine EM autoradiography. In vitro pulse labelling of salivary glands from late third instar larvae showed that the chromocentre heterochromatin replicates in synchrony with the euchromatin in the nucleus. Within the chromocentre region, the central compact mass, identified earlier as the alpha heterochromatin, did not incorporate ³H-thymidine at any stage of the S, while the surrounding beta heterochromatin was always labelled in nuclei with labelled euchromatin. In a second set of experiments, growing larvae from just after hatching till late third instar stages, were fed on food containing ³H-thymidine, and at the end of larval life, the incorporation in salivary gland nuclei was examined by EM autoradiography. A grain density analysis of the EM autoradiographs revealed that the alpha heterochromatin does not replicate at all from after hatching till late third instar while the beta heterochromatin replicates as much as the euchromatin. Non-replication of the alpha heterochromatin provides the explanation for the lowered amount of heterochromatin in the polytene nuclei compared to their diploid counterparts. Implications of these observations on the organization of chromocentre heterochromatin in polytene nuclei and its homology to the heterochromatic regions in mitotic chromosomes are discussed.     

Analysis of Y chromosome heterochromatin in Rumex thyrsiflorus

The Y chromosome heterochromatin in Rumex thyrsiflorus has been analyzed. In natural populations the Y chromosome shows a higher morphological variability than the X chromosome. The total duration of replication of Y chromosomes is about 2 hrs longer than that of euchromatin. Autoradiography with tritiated thymidine showed that chromocentres formed by Y chromosomes in interphase nuclei retain their heterochromatic form during DNA replication. — Y chromosome heterochromatin in interphase nuclei is stained pink, while the rest of the nucleus stains green after fast green-eosin staining for histones. — During the premeiotic stage of PMC development Y chromosomes are no longer visible as compact bodies and become more fuzzy in appearance. A diffuse state of Y coincides with intense RNA synthesis. Therefore genetic activity of Y chromosomes or their parts during premeiotic stage of microsporogenesis is postulated.     

Isolation, fractionation and template activity of the continuously-condensed chromatin of Euglena gracilis

A technique for isolating whole chromatin from nuclei of the lower eukaryote Euglena gracilis is presented. This chromatin, which appears under the electron microscope as uniformly condensed fibers, can, nevertheless, be subfractionated into distinct heterochromatic and euchromatic fractions. The euchromatin, comprising about 14% of the total DNA of the nucleus, contains over 80 % of the total endogenous RNA polymerase activity measured. The K_m for this enzyme is higher than that found for prokaryotes, but falls in the range found for other eukaryotes. Stability constants, calculated from cation-chromatin binding data, suggest that internal carboxyl groups of chromosomal proteins, at least, are involved in the condensation of Euglena chromatin. The relationship between Euglena chromatin and that of higher eukaryotes is discussed.     

Changes in Chromosomal Localization of Heterochromatin-binding Proteins during the Cell Cycle in Drosophila

We examined the heterochromatic binding of GAGA factor and proliferation disrupter (Prod) proteins during the cell cycle in Drosophila melanogaster and sibling species. GAGA factor binding to the brown^Dominant AG-rich satellite sequence insertion was seen at metaphase, however, no binding of GAGA factor to AG-rich sequences was observed at interphase in polytene or diploid nuclei. Comparable mitosis-specific binding was found for Prod protein to its target satellite in pericentric heterochromatin. At interphase, these proteins bind numerous dispersed sites in euchromatin, indicating that they move from euchromatin to heterochromatin and back every cell cycle. The presence of Prod in heterochromatin for a longer portion of the cell cycle than GAGA factor suggests that they cycle between euchromatin and heterochromatin independently. We propose that movement of GAGA factor and Prod from high affinity sites in euchromatin occurs upon condensation of metaphase chromosomes. Upon decondensation, GAGA factor and Prod shift from low affinity sites within satellite DNA back to euchromatic sites as a self-assembly process.     

Differential Uptake of Tritiated Thymidine into Hetero- and Euchromatin in Melanoplus and Secale

Grasshoppers of the species Melanoplus differentialis were injected with tritium-labelled thymidine. At intervals thereafter autoradiographic stripping film was applied over Feulgen squashes and sections. In this species during early prophase of meiosis the sex chromosome forms a heterochromatic block large enough to be resolved in tritium autoradiographs. A study of the squash preparations reveals that the sex chromosome is synthesizing DNA at a different period of time from the euchromatic autosomes. Since there is a developmental sequence of spermatocyte cysts along the testicular tubes it is possible from the sections to show that the heterochromatin synthesizes DNA later than does the euchromatin. To find out whether the results obtained in Melanoplus were characteristic of heterochromatin in general, young seedlings of rye were grown in a tritiated thymidine solution and Feulgen squashes were made as for Melanoplus. In rye leaf nuclei there is a large block of heterochromatin constituted by the proximal regions of the chromosomes and a euchromatic one formed by the median and distal regions of the same chromosomes. Here also the heterochromatin synthesizes DNA at a different period of time from the euchromatin. It is concluded that in rye the asynchrony of synthesis occurs within each chromosome. Counts of silver grains over the two types of chromatin in nuclei of Melanoplus and Secale disclosed that the number of grains per unit area was two to three times higher over the heterochromatin. To check the DNA content, Feulgen photometric measurements were made of Melanoplus nuclei at the same stage. The Feulgen and grain counts agree in showing that the heterochromatin contains two to three times more DNA per unit area than the euchromatin.     

Critical electrolyte concentration of the heterochromatin and euchromatin of Triatoma infestans

The binding of toluidine blue molecules under Mg2+ competitive staining conditions was investigated in chromocentres and the euchromatin of single- and multi-chromocentred nuclei of Triatoma infestans Malpighian tubule cells. It was demonstrated that the chromocentre of single-chromocentred nuclei exhibited the largest critical electrolyte concentration (CEC) value (0.4 M), followed by the chromocentres of multi-chromocentred nuclei (0.3 M) and the euchromatin (0.2 M). The differences in CEC values were assumed to be due to differences in availability of free DNA phosphates and in packing states of the DNA-protein complexes of these chromatin types. Differences in chromatin supra-organization were evident for the chromocentral heterochromatin of single vs multi-chromocentred nuclei. This was also valid for the chromocentral heterochromatin in some multi-chromocentred nuclei, when one of the heterochromatic bodies was especially larger than the others.     

Histone modifications in Arabidopsis- high methylation of H3 lysine 9 is dispensable for constitutive heterochromatin

N-terminal modifications of nucleosomal core histones are involved in gene regulation, DNA repair and recombination as well as in chromatin modeling. The degree of individual histone modifications may vary between specific chromatin domains and throughout the cell cycle. We have studied the nuclear patterns of histone H3 and H4 acetylation and of H3 methylation in Arabidopsis. A replication-linked increase of acetylation only occurred at H4 lysine 16 (not for lysines 5 and 12) and at H3 lysine 18. The last was not observed in other plants. Strong methylation at H3 lysine 4 was restricted to euchromatin, while strong methylation at H3 lysine 9 occurred preferentially in heterochromatic chromocenters of Arabidopsis nuclei. Chromocenter appearance, DNA methylation and histone modification patterns were similar in nuclei of wild-type and kryptonite mutant (which lacks H3 lysine 9-specific histone methyltransferase), except that methylation at H3 lysine 9 in heterochromatic chromocenters was reduced to the same low level as in euchromatin. Thus, a high level of H3methylK9 is apparently not necessary to maintain chromocenter structure and does not prevent methylation of H3 lysine 4 within Arabidopsis chromocenters.     

Heterochromatin and histone phosphorylation

Histone phosphorylation and nuclear structure have been compared in cultured cell lines of two related species of deer mice, Peromyscus crinitus and Peromyscus eremicus, which differ greatly in their heterochromatin contents but which contain essentially the same euchromatin content. Flow microfluorometry measurements indicated that P. eremicus contained 36% more DNA than did P. crinitus, and C-band chromosome staining indicated that the extra DNA of P. eremicus existed as constitutive heterochromatin. Two striking differences in interphase nuclear structure were observed by electron microscopy. Peromyscus crinitus nuclei contained small clumps of heterochromatin and a loose, amorphous nucleolus, while P. eremicus nuclei contained large, dense clumps of heterochromatin and a densely structured, well defined, nucleolonema form of nucleolus. Incorporation of ³²PO₄ into histones indicated that the steady-state phosphorylation of H1 was identical in P. crinitus and P. eremicus cells. In contrast, the phosphorylation rate of H2a was 58% greater in the highly heterochromatic chromatin of P. eremicus cells than in the lesser heterochromatic chromatin of P. crinitus cells, suggesting an involvement of H2a phosphorylation in heterochromatin structure. It is suggested that the three histone phosphorylations related to cell growth (H1, H2a, and H3) may be associated with different levels of chromatin organization: H1 interphase phosphorylation with some submicroscopic (molecular) level of organization, H2a phosphorylation with a higher level of chromatin organization found in heterochromatin, and H3 and H1 superphosphorylation with the highest level of chromatin organization observed in condensed chromosomes.     

The chromosomes of Puschkinia libanotica during mitosis

The chromosome complement of Puschkinia libanotica is described. In addition to five pairs of A chromosomes plants may possess up to 7 B chromosomes. Part of the long arm of the B chromosome gives rise to a heterochromatic mass in interphase nuclei and this can be seen to be a double structure in G₁ nuclei and a quadruple structure in G₂ nuclei. It is believed that these configurations represent the pre- and post-replication forms of subchromatids in the heterochromatic segment of the B chromosome. Microdensitometry of metaphase chromosomes shows that the segment of the B chromosome that is heterochromatic during interphase has no more DNA per unit volume than any of the euchromatic A chromosomes.     

Alpha and beta heterochromatin in polytene chromosome 2 ofDrosophila melanogaster

The formation of alpha and beta heterochromatin in chromosomes of Drosophila melanogaster was studied in salivary glands (SGs) and pseudonurse cells (PNCs). In SGs of X0, XY, XYY, XX and XXY individuals the amounts of alpha heterochromatin were similar, suggesting that the Y chromosome does not substantially contribute to alpha heterochromatin formation. Pericentric heterochromatin developed a linear sequence of blocks in PNCs, showing morphology of both alpha and beta heterochromatin. In situ hybridization with Rsp sequences (H _o clone) revealed that the most proximal heterochromatic segment of the mitotic map (region h39) formed a polytenized block in PNCs. Dot analysis showed that the clone had a hybridization rate with PNC-DNA very close to that with DNA from mainly diploid head cells, whereas the homologous SG-DNA was dramatically underrepresented. A similar increase of DNA representation in PNC was found for AAGAC satellite DNA. The mitotic region h44 was found not to polytenize in the SG chromosome, whereas in PNC chromosome 2 this region was partly polytenized and presented as an array of several blocks of alpha and beta heterochromatin. The mapping of deficiencies with proximal breakpoints in the most distal heterochromatin segments h35 in arm 2L and h46 in 2R showed that the mitotic eu-heterochromatin transitions were located in SG chromosomes distally to the polytene 40E and 41C regions, respectively. Thus, the transition zones between mitotic hetero- and euchromatin are located in banded polytene euchromatin. A scheme for dynamic organization of pericentric heterochromatin in nuclei with polytene chromosomes is proposed. Received: 17 November 1995; in revised form: 10 April 1996 / Accepted: 18 September 1996     

Dauer der DNS-Replikation von Eu- und Heterochromatin bei Microtus agrestis

The duration of DNA replication of eu- and heterochromatin in kidney epithelial cell cultures of female Microtus agrestis was determined with combined H³-thymidine pulse labelling and cytophotometric determination of Feulgen DNA. The average duration of the total cell cycle was 23.3 hrs, with a G1 period of 14.6 hrs, S period of 5 hrs, G2 period of 2.7 hrs, and mitosis of 1 hr. The replication time of eu- and heterochromatin was determined by the frequency of the different labelling patterns after pulse labelling. The time sequence of the labelling patterns was ascertained by DNA measurements. During the S period, euchromatin replicates at first alone for 3 hrs (60% of the length of S) and 1 hr (19.3%) together with heterochromatin. During the last hour (20.7%), only heterochromatic regions replicate. The sex chromatin part of the one X chromosome starts synthesis 20 minutes (7.3% of S) before the remainder of the heterochromatic X material and ends 30 minutes (9.7% of S) prior to the termination of the S period. Replication of euchromatin takes about 80% of the duration of the total S period, whereas that of heterochromatin takes only 40%.

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Mit dankenswerter Unterstützung durch die Deutsche Forschungs-Gemein-schaft.     

Underreplication during polytenization?

Summary Recent cytophotometric DNA determinations and results of labeling experiments are compared with results of biochemical experiments concerning larval polytene salivary gland nuclei of Drosophila melanogaster. Recent publications (Dennhöfer 1981; 1982 a, b) demonstrate that methodological errors both in hydrolysis of the DNA before Feulgen reaction and in interpretation of the cytophotometric values give raise to the hypothesis of heterochromatic underreplication during polytenization. It is concluded also that methodological difficulties cause the absence of polytene SAT-DNA in biochemical centrifugation experiments since, because of different solubilities of eu- and heterochromatic DNA, the latter is not resolved in DNA isolation procedures from polytene nuclei.     

Early replicating DNA in heterochromatin ofPlagiochila ovalifolia (Liverworts)

The timing of DNA replication of heterochromatin in malePlagiochila ovalifolia was investigated by the use of³H-thymidine autoradiography. The estimated duration of the mitotic cycle was as follows: S period, 19 hr: G₂+prophase, 10 hr; G₁+meta-, ana-, telophase, 5 hr; total mitotic cycle, 34 hr. The first appearance of silver grains over the chromosomes was observed at 8 hr after the beginning of pulse labelling at which time the silver grains were only over the euchromatic regions, not over the heterochromatic regions. This labelling pattern was also observed at 10 to 15 hr. The heterochromatic regions having more grains than the euchromatic regions were observed at 20 to 25 hr. These results show that the DNA of the heterochromatin of this species is replicated earlier than the euchromatin.     

HETEROCHROMATIN IN HUMAN MALE LEUKOCYTES

Tritiated thymidine was added to peripheral blood cultures containing phytohemagglutinin so that DNA synthesis in interphase nuclei of white blood cells in the human male could be studied. After 57 hours in culture, a large heterochromatic body with a central position is seen in unlabeled Feulgen-stained nuclei. In labeled nuclei in which DNA synthesis was taking place in both the eu- and heterochromatin at the time the thymidine became available, the heterochromatin shows a higher number of silver grains per unit area, accompanied by a stronger Feulgen reaction, an indication of its higher DNA content. The time of DNA synthesis in the heterochromatin blocks is different from that in the surrounding euchromatin. The large heterochromatic block is composed of chromosome segments gathered together around the nucleolus but it is not part of this organelle. In preparations stained with azure A and acid fuchsin for demonstrating both the nucleolus and the chromosomes, six distinctly heteropyenotic chromosome segments can be seen associated with the nucleolus. Cells of all size categories were found to incorporate tritiated thymidine. The distinct appearance of autosomal heterochromatin in white blood cells may be the result of the new physiological conditions to which the cells are subjected in the medium containing phytohemagglutinin.     

Intragenomic Distribution and Stability of Transposable Elements in Euchromatin and Heterochromatin of Drosophila melanogaster: Elements with Inverted Repeats Bari 1, hobo, and pogo

The elements of the Bari 1, hobo, and pogo transposon families that are located in euchromatin, heterochromatin, and on the Y chromosome have been identified, and their stability has been assessed by Southern blot analysis. The fraction of heterochromatic elements appears to be distinctive of all transposon families tested, except for Bari 1. Evidence for instability of heterochromatic elements is described. The analysis of unstable elements in different Drosophila stocks suggests that the host genome contributes to the stability/instability of transposon families. Received: 21 August 1996 / Accepted: 24 March 1997