Kinetics of DNA replication in the Indian muntjac chromosomes as studied by quantitative autoradiography

DNA replication patterns of individual chromosomes and their various euchromatic and heterochromatic regions were analyzed by means of quantitative autoradiography. The cultured cells of the skin fibroblast of a male Indian muntjac were pulse labeled with ³H-thymidine and chromosome samples were prepared for the next 32 h at 1–2 h intervals. A typical late replication pattern widely observed in heterochromatin was not found in the muntjac chromosomes. The following points make the DNA replication of the muntjac chromosomes characteristics: (1) Heterochromatin replicated its DNA in a shorter period with a higher rate than euchromatin. (2) Two small euchromatic regions adjacent to centromeric heterochromatin behaved differently from other portions of euchromatin, possessing shorter Ts, higher DNA synthetic rates and starting much later and ending earlier their DNA replication. (3) Segmental replication patterns were observed in the chromosomes 2 and 3 during the entire S phase. (4) Both homologues of the chromosome 3 showed a synchronous DNA replication pattern throughout the S phase except in the distal portion of the long arms during the mid-S phase.     

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.     

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.     

Relationship between sister-chromatid exchanges and heterochromatin or DNA replication in chromosomes of Crepis capillaris

The C-band patterns, DNA late replication patterns and distribution patterns of spontaneous and γ-ray-induced SCEs in Crepis capillaris chromosomes were studied. The fluorescence plus Giemsa (FPG) technique was used for detection of SCEs and late-replicating chromosome regions after unifilar incorporation of BrdU into DNA. An asynchronous replication of both euchromatic and heterochromatic chromosome regions was established. The frequency of SCEs is increased about 2-fold by 1.5 Gy γ-rays. The localization of the sites of SCEs was analyzed with special reference to eu- and heterochromatin and early- and late-replicating regions. The data obtained showed that SCEs were distributed nonrandomly along the chromosomes. Preferential occurrence of SCEs was observed in the following chromosome regions: at the junction between eu- and heterochromatic regions, the latter being rich in late-replicating DNA; at the junction between early- and late-replicating regions, the latter not being C-band positive. Certain heterochromatic regions were more rarely involved in SCEs than expected on the basis of their length. The lowest incidence of SCEs was found in the centromeric regions. Very similar distribution patterns of spontaneous and γ-ray-induced SCEs were observed. The possible role of the differences in the time of replication of the different chromosome regions in the formation of SCEs is discussed.     

Repetitive DNA sequences in Drosophila

The satellite DNAs of Drosophila melanogaster and D. virilis have been examined by isopycnic centrifugation, thermal denaturation, and in situ molecular hybridization. The satellites melt over a narrow temperature range, reassociate rapidly after denaturation, and separate into strands of differing buoyant density in alkaline CsCl. In D. virilis and D. melanogaster the satellites constitute respectively 41% and 8% of the DNA isolated from diploid tissue. The satellites make up only a minute fraction of the DNA isolated from polytene tissue. Complementary RNA synthesized in vitro from the largest satellite of D. virilis hybridized to the centromeric heterochromatin of mitotic chromosomes, although binding to the Y chromosome was low. The same cRNA hybridized primarily to the -heterochromatin in the chromocenter of salivary gland nuclei. The level of hybridization in diploid and polytene nuclei was similar, despite the great difference in total DNA content. The centrifugation and hybridization data imply that the -heterochromatin either does not replicate or replicates only slightly during polytenization. Similar but less extensive data are presented for D. melanogaster. — In D. melanogaster cRNA synthesized from total DNA hybridized to the entire chromocenter (- and -heterochromatin) and less intensely to many bands on the chromosome arms. The X chromosome was more heavily labeled than the autosomes. In D. virilis the X chromosome showed a similar preferential binding of cRNA copied from main peak sequences.—It is concluded that the majority of repetitive sequences in D. virilis and D. melanogaster are located in the - and -heterochromatin. Repetitive sequences constitute only a small percentage of the euchromatin, but they are widely distributed in the chromosomes. During polytenization the -heterochromatin probably does not replicate, but some or all of the repetitive sequences in the -heterochromatin and the euchromatin do replicate.     

Mammalian cell fusion

The behaviour of heterochromatin during premature chromosome condensation (PCC) was studied in a cell line of Microtus agrestis after fusion with mitotic HeLa cells. In the G₁- and G₂-PCC, the heterochromatic nature of the X-chromosomes was detectable by their intense staining. The pulverized appearance of the S-phase PCC was correlated with incorporation of ³H TdR into the DNA. Three types of S-PCC were observed. PCC with a pulverized appearance of: (a) only the autosomes (early S); (b) autosomes and X-chromosomes (mid S); and (c) only the X-chromosomes (late S). The behaviour of heterochromatin during replication, as observed by the PCC method, was no different from that of euchromatin. The data on the sequence of chromosome replication indicate that the centromeric regions of the X-chromosomes were the last segments to replicate. The completion of DNA synthesis in the X-chromosomes appears to be followed by progressive chromosome condensation during G₂ even before the actual initiation of prophase.     

Characterization of heterochromatin in Schistocerca gregaria by C- and N-banding methods

Mitotic and meiotic chromosomes of Schistocerca gregaria were C-, mild N- and strong N-banded. After C-banding, three out of eleven autosomes show, in addition to the centromeric C-bands, a second C-band. — The mild N-banding method produces a single N-band in each of only four chromosomes. With the exception of one N-band these mild N-bands correspond to the non-centromeric, second C-bands, indicating the heterochromatic character of at least three mild N-band regions. — The strong N-banding technique produces bands both at the C- and mild N-band positions and additionally a third band in one chromosome (M₈), not present after C- or mild N-banding. — The N-bands do not correspond to the nucleolus organizer regions. Because of the mechanisms of the N-banding methods, it is concluded that the centromeric heterochromatin, as well as the non-centromeric N-band regions, contain high quantities of non-histone proteins. Presumably a specific difference exists between the non-histone proteins in the centromeric and non-centromeric N-band regions because the centromeres are banded by the strong N-banding technique, but not after mild N-banding. It is concluded that the N-band regions (two exceptions) contain a heterochromatin type which has the following features in common with the -heterochromatin of Drosophila: C- as well as N-banding positive, high nonhistone protein content, repetitive and late replicating DNA. It is discussed whether the N-banded heterochromatin regions of Schistocerca contain that DNA fraction which is, like the Drosophila -heterochromatin, underreplicated in polyploid nuclei.     

The Drosophila Salivary Gland Chromocenter Contains Highly Polytenized Subdomains of Mitotic Heterochromatin

Peri-centromeric regions of Drosophila melanogaster chromosomes appear heterochromatic in mitotic cells and become greatly underrepresented in giant polytene chromosomes, where they aggregate into a central mass called the chromocenter. We used P elements inserted at sites dispersed throughout much of the mitotic heterochromatin to analyze the fate of 31 individual sites during polytenization. Analysis of DNA sequences flanking many of these elements revealed that middle repetitive or unique sequence DNAs frequently are interspersed with satellite DNAs in mitotic heterochromatin. All nine Y chromosome sites tested were underrepresented >20-fold on Southern blots of polytene DNA and were rarely or never detected by in situ hybridization to salivary gland chromosomes. In contrast, nine tested insertions in autosomal centromeric heterochromatin were represented fully in salivary gland DNA, despite the fact that at least six were located proximal to known blocks of satellite DNA. The inserted sequences formed diverse, site-specific morphologies in the chromocenter of salivary gland chromosomes, suggesting that domains dispersed at multiple sites in the centromeric heterochromatin of mitotic chromosomes contribute to polytene β-heterochromatin. We suggest that regions containing heterochromatic genes are organized into dispersed chromatin configurations that are important for their function in vivo.     

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.     

Assembly and characterization of heterochromatin and euchromatin on human artificial chromosomes

Background

Human centromere regions are characterized by the presence of alpha-satellite DNA, replication late in S phase and a heterochromatic appearance. Recent models propose that the centromere is organized into conserved chromatin domains in which chromatin containing CenH3 (centromere-specific H3 variant) at the functional centromere (kinetochore) forms within regions of heterochromatin. To address these models, we assayed formation of heterochromatin and euchromatin on de novo human artificial chromosomes containing alpha-satellite DNA. We also examined the relationship between chromatin composition and replication timing of artificial chromosomes.

Results

Heterochromatin factors (histone H3 lysine 9 methylation and HP1α) were enriched on artificial chromosomes estimated to be larger than 3 Mb in size but depleted on those smaller than 3 Mb. All artificial chromosomes assembled markers of euchromatin (histone H3 lysine 4 methylation), which may partly reflect marker-gene expression. Replication timing studies revealed that the replication timing of artificial chromosomes was heterogeneous. Heterochromatin-depleted artificial chromosomes replicated in early S phase whereas heterochromatin-enriched artificial chromosomes replicated in mid to late S phase.

Conclusions

Centromere regions on human artificial chromosomes and host chromosomes have similar amounts of CenH3 but exhibit highly varying degrees of heterochromatin, suggesting that only a small amount of heterochromatin may be required for centromere function. The formation of euchromatin on all artificial chromosomes demonstrates that they can provide a chromosome context suitable for gene expression. The earlier replication of the heterochromatin-depleted artificial chromosomes suggests that replication late in S phase is not a requirement for centromere function.

     

DNS-Replikationsmuster der Speicheldrüsen-Chromosomen von Chironomiden

The pattern of DNA-synthesis of the salivary gland chromosomes of Chironomus thummi thummi, Ch. th. piger, Ch. annularius, Ch. plumosus and Ch. melanotus was studied using H³-thymidine-autoradiography. Contrary to the previous conception the bands of the salivary gland chromosomes of Chironomus do not begin replication simultaneously. H³-thymidine incorporation in bands of high DNA content begins later than in bands with a lesser amount of DNA. This difference in time is very small in bands outside the kinetochore regions and not comparable to the asynchrony in replication of typical heterochromatin in the salivary gland chromosomes of Chironomus melanotus. Differences in the amount of DNA in homologous bands do not affect the onset of replication. — Bands of high DNA content are replicating during a longer time than those having less DNA. However, certain chromosome regions behave differently. In these regions bands of very low DNA content are synthesizing DNA during the whole replication cycle. Since no excessive increase of DNA could be observed in these regions it is supposed that in addition to the duplication of structural DNA an extra DNA is synthesized which disappears immediately from the chromosome. — At the end of the replication cycle in the salivary gland nuclei of the hybrid Chironomus th. thummi X Ch. th. piger a labeling pattern is found in the chromosomes of Ch. th. thummi which differs from that in the parental subspecies Ch. th. thummi.     

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.     

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.     

Intercalary heterochromatin in polytene chromosomes of <Emphasis Type="Italic">Drosophila melanogaster</Emphasis>

Intercalary heterochromatin consists of extended chromosomal domains which are interspersed throughout the euchromatin and contain silent genetic material. These domains comprise either clusters of functionally unrelated genes or tandem gene duplications and possibly stretches of noncoding sequences. Strong repression of genetic activity means that intercalary heterochromatin displays properties that are normally attributable to classic pericentric heterochromatin: high compaction, late replication and underreplication in polytene chromosomes, and the presence of heterochromatin-specific proteins. Late replication and underreplication occurs when the suppressor of underreplication protein is present in intercalary heterochromatic regions. Intercalary heterochromatin underreplication in polytene chromosomes results in free double-stranded ends of DNA molecules; ligation of these free ends is the most likely mechanism for ectopic pairing between intercalary heterochromatic and pericentric heterochromatic regions. No support has been found for the view that the frequency of chromosome aberrations is elevated in intercalary heterochromatin.     

Chromosomal replication in Drosophila virilis

About half of the diploid genome of D. virilis is -heterochromatic (Heitz, 1934) and contains the satellite sequences found in isopycnic CsCl density gradients (Gall et al, 1971; Steinemann, 1976). The thymidine incorporation behavior of this material in the course of S phase was monitored by autoradiography. Labelled interphase nuclei show three types of labelling patterns, label exclusively confined to either eu- or -heterochromatin, and simultaneous labelling of both fractions. Using the fraction of labelled mitotic index method, the duration of the DNA-synthetic period, t_s = 11.9 ± 4.3 h and G₂ period, t_{G2 + 1/2M} = 6.9 ± 3.8 h, were determined. On the assumption that the investigated brain cells belong to an exponentially growing cell population, the cell cycle is 22.9 h long and the G₁ period lasts t_G1=4.1 h. The a-heterochromatin begins to replicate later than euchromatin and continues alone after a phase of common replication of both fractions. Noteworthy is the asynchronous termination in the proximal -heterochromatic segments of different chromosomes. Within the S phase, the first 1 h of DNA replication is exclusively confined to euchromatin, followed by 8 h of replication in both eu- and -heterochromatin and terminated by 3 h of exclusive -heterochromatin replication. Thus euchromatin has a doubling time of about 9 h and -heterochromatin of about 11 h. The -heterochromatin of D. virilis is late and slow replicating.     

Contrasting response of euchromatin and heterochromatin to translocation in polytene chromosomes of Drosophila melanogaster

Studies on Feulgen-DNA content in the polytene chromosomes of D. melanogaster T(14)w ^m258-21 heterozygotes showed that when the euchromatic region 3D₁-E₂ is located next to the heterochromatic breakpoint it contains less DNA than in the non-translocated homologue (Hartmann-Goldstein and Cowell, 1976). In contrast to the region adjacent to the breakpoint, region 3C_1–10, which contains intercalary heterochromatin, shows more DNA in the translocated than in the non-translocated chromosome. Transposition may induce morphologically euchromatic regions containing putatively underreplicated sequences to undergo additional replication cycles. Region 2E₁-3A₄, distal to 3C₁ and at some distance from the heterochromatic breakpoint is apparently unaffected. Extended replication and reduced DNA content in regions which have undergone chromosomal rearrangement could be accounted for by varying degrees of blockage of replication in individual strands of the polytene chromosome.     

3H-Actinomycin-D binding to mitotic chromosomes of Drosophila melanogaster

The binding of ³H-AMD to the metaphase chromosomes of Drosophila melanogaster has been analyzed after two different periods of exposure to photographic emulsion. The entirely heterochromatic Y chromosome was markedly less labelled than euchromatin and other heterochromatic regions. Moreover, the few grains present on the Y chromosome were clustered in two regions, one localized in the middle of Y^S and the other in the proximal third of Y^L. This labelling pattern is not affected by removing histones with a 2-hour treatment with 2N HCl. It is suggested that the specific underlabelling of the Y chromosome reflects a peculiar AT richness.     

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.     

Chromosomal alterations in cell lines derived from mouse rhabdomyosarcomas induced by crystalline nickel sulfide

Summary Prior studies have shown a preferential decondensation (or fragmentation) of the heterochromatic long arm of the X chromosome of Chinese hamster ovary cells when treated with carcinogenic crystalline NiS particles (crNiS). In this report, we show that the heterochromatic regions of mouse chromosomes are also more frequently involved in aberrations than euchromatic regions, although the heterochromatin in mouse cells is restricted to centromeric regions. We also present the karyotypic analyses of four cell lines derived from tumors induced by leg muscle injections of crystalline nickel sulfide which have been analyzed to determine whether heterochromatic chromosomal regions are preferentially altered in the transformed genotypes. Common to all cell lines was the presence of minichromosomes, which are acrocentric chromosomes smaller than chromosome 19, normally the smallest chromosome of the mouse karyotype. The minichromosomes were present in a majority of cells of each line although the morphology of this extra chromosome varied significantly among the cell lines. C-banding revealed the presence of centromeric DNA and thus these minichromosomes may be the result of chromosome breaks at or near the centromere. In three of the four lines a marker chromosome could be identified as a rearrangement between two chromosomes. In the fourth cell line a rearranged chromosome was present in only 15% of the cells and was not studied in detail. One of the three major marker chromosomes resulted from a centromeric fusion of chromosome 4 while another appeared to be an interchange involving the centromere of chromosome 2 and possibly the telomeric region of chromosome 17. The third marker chromosome involves a rearrangement between chromosome 4 near the telomeric region and what appears to be the centromeric region of chromosome 19. Thus, in these three major marker chromosomes centromeric heterochromatic DNA is clearly implicated in two of the rearrangements and less clearly in the third. The involvement of centromeric DNA in the formation of even two of four markers is consistent with the previously observed preference in the site of action of crNiS for heterochromatic DNA during the early stages of carcinogenesis.