Asynchrony of DNA replication and mitotic spiralization along heterochromatic portions of Chinese hamster chromosomes

Sequence of DNA synthesis and mitotic chromosome spiralization along heterochromatic portions of the sex (X₁X₂) and of some marker chromosomes in cultured Chinese hamster cells were studied, employing two methods: study of segmentation pattern caused in chromosomes with colcemid, and autoradiography with tritiated thymidine. The heterochromatic portions of all chromosomes studied were characterized by striking internal asynchrony of DNA replication. In particular, they had segments that replicated relatively early. The short arm of the X₂ chromosome, heterochromatic in female somatic cells, had at least three such segments. Replication patterns of the long arms of the X₁ and X₂ chromosomes were different. In X₁ this arm contains several segments showing relatively early replication. The long arm of X₂ had no similar segments. The possible significance of the data obtained is discussed with regard to the problem of genetic inertness of heterochromatin. At the terminal stage of the S period, H³-thymidine seems to be incorporated into condensed chromatin of interphase nuclei. On the basis of the data obtained, it is proposed that during replication of heterochromatin consecutive despiralization of parts of it takes place.     

Codling moth cytogenetics: karyotype, chromosomal location of rDNA, and molecular differentiation of sex chromosomes.

We performed a detailed karyotype analysis in the codling moth, Cydia pomonella (L.) (Lepidoptera: Tortricidae), the key pest of pome fruit in the temperate regions of the world. The codling moth karyotype consisted of 2n = 56 chromosomes of a holokinetic type. The chromosomes were classified into 5 groups according to their sizes: extra large (3 pairs), large (3 pairs), medium (15 pairs), small (5 pairs), and dot-like (2 pairs). In pachytene nuclei of both sexes, a curious NOR (nucleolar organizer region) bivalent was observed. It carried 2 nucleoli, each associated with one end of the bivalent. FISH with an 18S ribosomal DNA probe confirmed the presence of 2 clusters of rRNA genes at the opposite ends of the bivalent. In accordance with this finding, 2 homologous NOR chromosomes were identified in mitotic metaphase, each showing hybridization signals at both ends. In highly polyploid somatic nuclei, females showed a large heterochromatin body, the so-called sex chromatin or W chromatin. The heterochromatin body was absent in male nuclei, indicating a WZ/ZZ (female/male) sex chromosome system. In keeping with the sex chromatin status, pachytene oocytes showed a sex chromosome bivalent (WZ) that was easily discernible by its heterochromatic W thread. To study molecular differentiation of the sex chromosomes, we employed genomic in situ hybridization (GISH) and comparative genomic hybridization (CGH). GISH detected the W chromosome by strong binding of the Cy3-labelled, female-derived DNA probe. With CGH, both the Cy3-labelled female-derived probe and Fluor-X labelled male-derived probe evenly bound to the W chromosome. This suggested that the W chromosome is predominantly composed of repetitive DNA sequences occurring scattered in other chromosomes but accumulated in the W chromosome. The demonstrated ways of W chromosome identification will facilitate the development of genetic sexing strains desirable for pest control using the sterile insect technique.     

Sex chromosome pairing and sex chromatin bodies in W-Z translocation strains of Ephestia kuehniella (Lepidoptera).

Structure and pairing behavior of sex chromosomes in females of four T(W;Z) lines of the Mediterranean flour moth, Ephestia kuehniella, were investigated using light and electron microscopic techniques and compared with the wild type. In light microscopic preparations of pachytene oocytes of wild-type females, the WZ bivalent stands out by its heterochromatic W chromosome strand. In T(W;Z) females, the part of the Z chromosome that was translated onto the W chromosome was demonstrated as a distal segment of the neo-W chromosome, displaying a characteristic non-W chromosomal chromomere-interchromomere pattern. This segment is homologously paired with the corresponding part of a complete Z chromosome. In contrast with the single ball of heterochromatic W chromatin in highly polyploid somatic nuclei of wild-type females, the translocation causes the formation of deformed or fragmented W chromatin bodies, probably owing to opposing tendencies of the Z and W chromosomal parts of the neo-W. In electron microscopic preparations of microspread nuclei, sex chromosome bivalents were identified by the remnants of electron-dense heterochromatin tangles decorating the W chromosome axis, by the different lengths of the Z and W chromosome axes, and by incomplete pairing. No heterochromatin tangles were attached to the translocated segment of the Z chromosome at one end of the neo-W chromosome. Because of the homologous pairing between the translocation and the structurally normal Z chromosome, pairing affinity of sex chromosomes in T(W;Z) females is significantly improved. Specific differences observed among T(W;Z)1-4 translocations are probably due to the different lengths of the translocated segments.     

The structure of heterochromatic DNA is altered in polyploid cells of Drosophila melanogaster.

DNA sequences within heterochromatin are often selectively underrepresented during development of polyploid chromosomes, and DNA molecules of altered structure are predicted to form as a consequence of the underrepresentation process. We have identified heterochromatic DNAs of altered structure within sequences that are underrepresented in polyploid cells of Drosophila melanogaster. Specifically, restriction fragments that extend into centric heterochromatin of the minichromosome Dp(1;f)1187 are shortened in polyploid cells of both the ovary and salivary gland but not in the predominantly diploid cells of the embryo or larval imaginal discs and brains. Shortened DNA molecules were also identified within heterochromatic sequences of chromosome III. These results suggest that the structure of heterochromatic DNA is altered as a general consequence of polyploid chromosome formation and that the shortened molecules identified form as a consequence of heterochromatic underrepresentation. Finally, alteration of heterochromatic DNA structure on Dp(1;f)1187 was not correlated with changes in the variegated expression of the yellow gene located on the minichromosome.     

Spatial distribution of sperm-derived chromatin in zygotes determined by fluorescence in situ hybridization.

Fluorescence in situ hybridization was used to determine the spatial distribution of chromatin in zygote pronuclei. A hybrid system involving golden hamster eggs and individual human sperm permitted use of DNA probes specific for the entire human chromosome 4, for the heterochromatic region on the long arm of the human Y chromosome and for unique DNA sequences on human chromosome 19. Chromosome 4 occupied a circumscribed domain in the pronuclei, similar to findings in somatic interphases. Unlike the situation in somatic interphases, the Y heterochromatin was extended throughout the first cell cycle. Pronuclear chromatin was extended 3- to 4-fold compared to somatic interphase chromatin. The extended pronuclear chromatin conformation is likely to affect a zygote's susceptibility to environmental hazards.     

Heterochromatin,gene position effect and gene silencing

Genomes of higher eukaryotes consist of two types of chromatin: euchromatin and heterochromatin. Heterochromatin is densely packed material typically localized in telomeric and pericentric chromosome regions. Euchromatin transferred by chromosome rearrangements in the vicinity of heterochromatin is inactivated and acquires morphological properties of heterochromatin in the case of position effect variegation. One of the X chromosomes in mammal females and all paternal chromosome set in coccides become heterochromatic. The heterochromatic elements of the genome exhibit similar structural properties: genetic inactivation, compaction, late DNA replication at the S stage, and underrepresentation in somatic cells. The genetic inactivation and heterochromatin assembly are underlain by a specific genetic mechanism, silencing, which includes DNA methylation and posttranslational histone modification provided by the complex of nonhistone proteins. The state of silencing is inherited in cell generations. The same molecular mechanisms of silencing shared by all types of heterochromatic regions, be it unique or highly repetitive sequences, suggest the similar organization of these regions. No type of heterochromatin is a permanent structure as they all are formed at the strictly definite stages of early embryogenesis. Based on the bulk of evidence accumulated today, heterochromatin can be regarded as a morphological manifestation of genetic silencing.     

Heterochromatin, Position Effect, and Genetic Silencing

Genomes of higher eukaryotes consist of two types of chromatin: euchromatin and heterochromatin. Heterochromatin is densely packed material typically localized in telomeric and pericentric chromosome regions. Euchromatin transferred by chromosome rearrangements in the vicinity of heterochromatin is inactivated and acquires morphological properties of heterochromatin in the case of position effect variegation. One of the X chromosomes in mammal females and all paternal chromosome set in coccides become heterochromatic. The heterochromatic elements of the genome exhibit similar structural properties: genetic inactivation, compaction, late DNA replication at the S stage, and underrepresentation in somatic cells. The genetic inactivation and heterochromatin assembly are underlain by a specific genetic mechanism, silencing, which includes DNA methylation and posttranslational histone modification provided by the complex of nonhistone proteins. The state of silencing is inherited in cell generations. The same molecular mechanisms of silencing shared by all types of heterochromatic regions, be it unique or highly repetitive sequences, suggest the similar organization of these regions. No type of heterochromatin is a permanent structure as they all are formed at the strictly definite stages of early embryogenesis. Based on the bulk of evidence accumulated today, heterochromatin can be regarded as a morphological manifestation of genetic silencing.     

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.     

Molecular and cytological characterization of repetitive DNA sequences from the centromeric heterochromatin of <Emphasis Type="Italic">Sciara coprophila</Emphasis>

Sciara coprophila (Diptera, Nematocera) constitutes a classic model to analyze unusual chromosome behavior such as the somatic elimination of paternal X chromosomes, the elimination of the whole paternal, plus non-disjunction of the maternal X chromosome at male meiosis. The molecular organization of the heterochromatin in S. coprophila is mostly unknown except for the ribosomal DNA located in the X chromosome pericentromeric heterochromatin. The characterization of the centromeric regions, thus, is an essential and required step for the establishment of S. coprophila as a model system to study fundamental mechanisms of chromosome segregation. To accomplish such a study, heterochromatic sections of the X chromosome centromeric region from salivary glands polytene chromosomes were microdissected and microcloned. Here, we report the identification and characterization of two tandem repeated DNA sequences from the pericentromeric region of the X chromosome, a pericentromeric RTE element and an AT-rich centromeric satellite. These sequences will be important tools for the cloning of S. coprophila centromeric heterochromatin using libraries of large genomic clones.     

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.     

Heterochromatin organization in the nucleus of Indian muntjac (Muntiacus muntjak)

The heterochromatin in Indian muntjac (Muntiacus muntjak) is located at the periphery of primary constrictions of all the chromosomes. The X chromosome contains significantly larger amounts of heterochromatin than the rest of the complement by C-banding technique. However, the small portion of C-band region was found to be resistant by restriction endonuclease HaeIII (5'...GG decreases CC...3') and was clearly visible on the nucleus. Therefore, the position of this large heterochromatic segment is examined at somatic metaphases. The distribution of the heterochromatin of the X chromosome observed in Indian muntjac is contrary to the general pattern observed in other species, i.e., the chromosomes consisting greater amount of heterochromatin are located more peripherally than those with lesser amount. However, the smaller Y chromosome (Y1) is frequently found at the periphery. The present findings suggest that the role of heterochromatin organization in the nucleus vary between different heterochromatic segments of the same species and vary from species to species.     

Differential sensitivity of constitutive and facultative heterochromatin in orthopteran chromosomes to digestion by DNaseI

In situ pancreatic DNaseI digestions were used as probes to study the structural organization of facultative and constitutive heterochromatin during both mitotic and meiotic divisions. Three different types of heterochromatic regions from three insect species were chosen for this study. These regions had been previously characterized by in situ treatments with restriction endonucleases (AT and GC rich DNA sequences). Progressive increase in DNaseI concentration (from 10 to 200 ng/ml) or in incubation time (from 5 to 30 min) revealed a specific pattern of sequential digestion of the constitutive heterochromatic regions, the centromeric ones (AT-rich DNA) being the most resistant to DNaseI action. The interstitial C-bands (with AT or GC-rich DNA) were more sensitive to DNaseI, and the band 4.4 from Baetica ustalata was the most resistant of the non-centromeric bands. Similar results were obtained during meiosis, but increased accessibility to DNAseI was observed compared to mitosis. DNA methylation in the non-centromeric band 4.4 of B. ustulata could be responsible for its differential digestion with respect to the remaining intercalar heterochromatin. Facultatively heterochromatic regions (X chromosomes) were found to exhibit a differential response to DNaseI attack from mitosis to meiosis. While they behaved as cuchromatin during mitosis, they were the most resistant together with centromeric heterochromatin regions, during metaphase I and II. The different responses to digestion of the X chromosome and X-derived regions between somatic and meiotic divisions are probably a consequence of the changes in the organization of this chromosome during the facultative heterochromatinization process.