Experimental condensation inhibition in constitutive and facultative heterochromatin of mammalian chromosomes

What drives the dramatic changes in chromosome structure during the cell cycle is one of the oldest questions in genetics. During mitosis, all chromosomes become highly condensed and, as the cell completes mitosis, most of the chromatin decondenses again. Only chromosome regions containing constitutive or facultative heterochromatin remain in a more condensed state throughout interphase. One approach to understanding chromosome condensation is to experimentally induce condensation defects. 5-Azacytidine (5-aza-C) and 5-azadeoxycytidine (5-aza-dC) drastically inhibit condensation in mammalian constitutive heterochromatin, in particular in human chromosomes 1, 9, 15, 16, and Y, as well as in facultative heterochromatin (inactive X chromosome), when incorporated into late-replicating DNA during the last hours of cell culture. The decondensing effects of 5-aza-C analogs, which do not interfere with normal base pairing in substituted duplex DNA, have been correlated with global DNA hypomethylation. In contrast, decondensation of constitutive heterochromatin by incorporation of 5-iododeoxyuridine (IdU) or other non-demethylating base analogs, or binding of AT-specific DNA ligands, such as berenil and Hoechst 33258, may reflect an altered steric configuration of substituted or minor-groove-bound duplex DNA. Consequently, these compounds exert relatively specific effects on certain subsets of AT-rich constitutive heterochromatin, i.e. IdU on human chromosome 9, berenil on human Y, and Hoechst 33258 on mouse chromosomes, which provide high local concentrations of IdU incorporation sites or DNA-ligand-binding sites. None of these non-demethylating compounds affect the inactive X chromosome condensation. Structural features of chromosomes are largely determined by chromosome-associated proteins. In this light, we propose that both DNA hypomethylation and steric alterations in chromosomal DNA may interfere with the binding of specific proteins or multi-protein complexes that are required for chromosome condensation. The association between chromosome condensation defects, genomic instability, and epigenetic reprogramming is discussed. Chromosome condensation may represent a key ancestral mechanism for modulating chromatin structure that has since been realloted to other nuclear processes.     

Heterogeneity of constitutive heterochromatin in somatic Syrian hamster chromosomes.

Syrian hamster constitutive heterochromatin was analyzed for C-band distribution and for BrU late-replication pattern. Characteristic for this species is relatively large amounts of sex-chromosome and autosomal heterochromatin. The distribution of constitutive heterochromatin was determined. The long term of the X chromosome, the whole Y, the short arms of 8 autosomal pairs, the long arm of the smallest metacentric pair, and the centromeric regions of 12 pairs stained intensely dark on C-band preparations. In contrast to the heterochromatin in the centromeric regions, the autosomal short-arm heterochromatin has an increased susceptibility to the denaturation process, as indicated by prolonged exposure to NaOH or Ba(OH)2. Such further exposure to denaturing agents results in an intense dark stain only on the sex-chromosome heterochromatin and centromeric regions of the autosomes. The BrdU late-replication pattern demonstrated that the late-replicating regions correspond to C-bands. Centromeric regions replicate late in the S phase; however, no centromeric region is among the latest replicating segments of the complement. Centromeric and noncentromeric heterochromatin are two distinct categories of constitutive heterochromatin.     

Immunocytogenetics. V. A highly conserved NOR antigen (He) is facultatively associated with nucleolar or nucleoplasmic granules

A new protein antigen of the nucleolus organizer region (NOR), designated He, was recognized by human autoantibodies obtained from a patient with Raynaud phenomenon. In mitotic cells of all vertebrate species tested. He serum selectively immunostained the chromosomal NORs. A completely unexpected characteristic of the He antigen was its location during interphase. In mammalian cell substrates, it was concentrated in numerous nucleoplasmic granules, with minor amounts of the antigen uniformly distributed throughout the entire nucleus. In interphase nuclei of lower vertebrate cells, however, the antigen was preferentially located in the nucleolus. The antigenicity of He is not dependent on RNA or DNA; its cytochemical properties operationally classify it as a nonhistone component of the chromosome scaffold. The He antigen was present in the residual nucleolar structures of cells that were not at all active in rRNA synthesis, such as mammalian late spermatids and amphibian erythrocytes.     

Identification of isolated metaphase chromosomes. II. A comparison with the recognizability of chromosomes in metaphase plates

The metaphase chromosomes (MC) isolated from the Chinese hamster cells were identified with the aid of differential staining (G-bands). It was shown that differences in the relative recognizability of MC in metaphase plates and after their isolation are determined by changes in composition of isolated MC, rather than by those in staining capacity of MC after their isolation. The frequencies of identified MC are constant and independent upon the type of MC preparations and relation between identified and unidentified MC in certain preparations. At allows to apply the described method for the analysis of chromosome fractionation, using changes in frequencies of identified MC as a criterion of efficiency of the fractionation method. Possible ways of increasing the recognizability level of isolated MC are discussed.     

Identification of a nonhistone chromosomal protein associated with heterochromatin in Drosophila melanogaster and its gene.

Monoclonal antibodies were prepared against a fraction of nuclear proteins of Drosophila melanogaster identified as tightly binding to DNA. Four of these antibodies were directed against a 19-kilodalton nuclear protein; immunofluorescence staining of the polytene chromosomes localized the antigen to the alpha, beta, and intercalary heterochromatic regions. Screening of a lambda gt11 cDNA expression library with one of the monoclonal antibodies identified a recombinant DNA phage clone that produced a fusion protein immunologically similar to the heterochromatin-associated protein. Polyclonal sera directed against the bacterial lacZ fusion protein recognized the same nuclear protein on Western blots. A full-length cDNA clone was isolated from a lambda gt10 library, and its DNA sequence was obtained. Analysis of the open reading frame revealed an 18,101-dalton protein encoded by this cDNA. Two overlapping genomic DNA clones were isolated from a Charon 4 library of D. melanogaster with the cDNA clone, and a restriction map was obtained. In situ hybridization with these probes indicated that the gene maps to a single chromosome location at 29A on the 2L chromosome. This general strategy should be effective for cloning the genes and identifying the genetic loci of chromosomal proteins which cannot be readily assayed by other means.     

Mechanisms of chromosome banding : VI. Whole mount electron microscopy of banded metaphase chromosomes and a comparison with pachytene chromosomes

Chinese hamster chromosomes, banded by exposure to actinomycin D during the G 2 period, were examined by whole mount electron microscopy. Bands of condensed chromatin were present in unstained preparations that were not fixed with methanol-acetic acid indicating that the differential condensation of chromatin plays a role in banding by this technique. There was a tendency for interdigitation of the chromatin of the homologous bands on sister chromatids. Since previous studies had shown that the bands of mitotic chromosomes matched the chromomeres of meiotic chromosomes, whole mount electron microscope preparations of pachytene chromosomes were also examined. These suggest that in addition to condensation the chromatin of the chromomeres may also have a higher density of attachment sites to the lateral element of the synaptonemal complex, and probably to the nuclear membrane in interphase cells.     

The constitutive heterochromatin in chromosomes of Fritillaria Sp., as revealed by Giemsa banding.

The incidence of C-bands (constitutive heterochromatin), as determined by differential Giemsa staining, was studied in the chromosomes of 56 species, varietal forms and subgenera of Fritillaria and 30 of them are illustrated. With the exception of the subgenera Korolkowi, a supposed link between lilies and fritillaries, and chromsome complements of all plants contained bands. There were wide differences in the size and number of these bands among species both within and between groups. In those with the largest and most abundant bands, there was a pronounced tendency for centromeric localization, both in Old and New World species. The Giemsa positive centromeres were masked when this occurred. Heteromorphy in respect of banding occurred in most species. The relation of repetitive DNA sequences with heterochromatin is discussed, as is also the problem of evolution in Fritillaria.     

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.     

Sterility in hybrid cattle. I. Distribution of constitutive heterochromatin and nucleolus organizer regions in somatic and meiotic chromosomes.

The distribution of constitutive heterochromatin and nucleolus organizer regions (NOR's) in somatic as well as in meiotic chromosomes of Bos taurus, Bos banteng, Bison bison, and their hybrids are analyzed. C-bands are present in the centromeric regions of every autosome. The X chromosome does not show a distinct C-band in the centromeric region, whereas the Y chromosome contains an appreciable amount of C-band material. In somatic metaphases, NOR's are present on the telomeric ends of five pairs of autosomes. During pachytene, five autosomal bivalents contain NOR's on their terminal ends. Meiotic preparations made from sterile bulls did not contain stages beyond the degenerating pachytene, which are C-banding, more frequently showed clustering of heterochromatin than did the pachytene stage in normal bulls.     

Random association of Epstein-Barr virus genomes with host cell metaphase chromosomes in Burkitt''s lymphoma-derived cell lines.

The random association of Epstein-Barr virus DNA with host cell metaphase chromosomes of all sizes in Burkitt's lymphoma-derived cell lines was demonstrated by two substantially different techniques, namely fluorescence-activated chromosome sorting and in situ hybridization. The nature and potential importance of this association are discussed.     

Distribution of constitutive heterochromatin in Hela and HEp-2 cell lines

Summary Despite the fact that HeLa and HEp-2 cell lines have been established respectively from a female and a male patient, the frequent loss of the Y chromosome makes it difficult to discriminate the two cell types. The technique of centromeric localization of heterochromatin, however, facilitates more definite identification of the two cell types. Giemsa positive centromeric constitutive heterochromatin blocks were induced within the intact metaphase chromosome preparations of Hela and HEp-2 cells. The Hela cell population had a single heterochromatin marker chromosome, whereas the HEp-2 cell line was found to possess two types of heterochromatin markers. The distinctive patterns of distribution of constitutive heterochromatin of these three chromosomes served as the guides in tracing the presumptive cytological pathways for their orgin.

---

Zusammenfassung Trotz der Tatsache, daß Hela- und HEp-2-Zellinien jeweils von einem weiblichen und einem männlichen Patienten stammen, erschwert der häufige Verlust des Y-Chromosoms eine Unterscheidung der beiden Zelltypen. Der Nachweis des zentromernahen Heterochromatins jedoch ermöglicht eine zuverlässigere Erkennung dieser beiden Zelltypen. Die Hela-Zellpopulation hat ein einzelnes, durch das Heterochromation gekennzeichnetes Marker-Chromosom, während die HEp-2-Zellinie deren 2 besitzt. Das distinkte Verteilungsmuster des konstitutiven Heterochromatons dieser 3 Chromosomen dient dazu, die vermutliche cytologische Herkunft zu interpretieren.

---

---

Supported in part by the Robert A. Welch Foundation, The National Foundation —March of Dimes and USPHS Grant No. FR-05425.     

A tandemly repeated DNA sequence is associated with both knob-like heterochromatin and a highly decondensed structure in the meiotic pachytene chromosomes of rice

Highly repetitive tandem DNA sequence repeats are often associated with centromeric and telomeric regions of eukaryotic chromosomes. The rice tandem repeat Os48 is organized as long arrays of a 355 bp monomer and is mainly located in the telomeric regions. The chromosomal locations of the Os48 sequence were determined by fluorescence in situ hybridization (FISH) on rice pachytene chromosomes. The majority of the Os48 loci are associated with brightly 4',6-diamidino-2-phenylindole (DAPI)-stained and knob-like heterochromatin in rice pachytene chromosomes. As with other DNA sequences located in the heterochromatic regions, the cytosines of the CG and C(A/T)G sites within the Os48 repeat are heavily methylated. Surprisingly, a proportion of the FISH signals are highly decondensed and deviate significantly from the DAPI-stained periphery of the pachytene chromosomes. This highly decondensed chromatin structure has not been reported in pachytene chromosomes prepared from alcohol/acid-fixed meiotic samples in any other eukaryotic species. The condensation of the Os48 sequences is dynamic during prophase I of meiosis. The FISH signals derived from the Os48 repeat progress from a condensed configuration between leptonema and early pachynema into a decondensed structure from middle pachynema to diakinesis, and then return to a condensed form at metaphase I.     

Rat liver chromatin. Distribution of histone and nonhistone proteins in eu- and heterochromatin.

Rat liver chromatin was sheared and separated into template-active (euchromatin) and template-inactive (heterochromatin) fractions by glycerol gradient centrifugation. Chromosomal proteins associated with the chromatin fractions were analyzed by sodium dodecyl sulfate-polyacrylamide-gel electrophoresis. Histone composition did not vary qualitatively, but more histone protein was consistently found associated with the euchromatin fractions. Nonhistone protein banding patterns for these chromatin fractions exhibited marked heterogeneity, with a number of bands unique to either eu- or heterochromatin.     

Prevalence of B chromosomes in Orthoptera is associated with shape and number of A chromosomes

We analyze the prevalence of B chromosomes in 1,601 species of orthopteran insects where chromosome number and shape are known. B chromosomes have been reported in 191 of these species. Bs are not uniformly distributed among orthopteran superfamilies, with evident hotspots in the Pyrgomorphoidea (32.3% of species carrying Bs), Grylloidea (14.9%), Acridoidea (14.6%) and Tetrigoidea (14.3%). As expected under the theory of centromeric drive, we found a correlation between B chromosome presence and A chromosome shape-Bs are more frequent in karyotypes with more acrocentric A chromosomes. We also found that Bs are less common in species with high chromosome numbers and appear to be most common at the modal chromosome number (2n = 24). Study effort, measured for each genus, was not associated with B prevalence, A chromosome shape or A chromosome number. Our results thus provide support for centromeric drive as an important and prevalent force in the karyotypic evolution of Orthoptera, just as it appears to be in mammals. We suggest that centromeric drive may provide a mechanistic explanation for White's principle of karyotypic orthoselection.     

Robertsonian polymorphism and constitutive heterochromatin distribution in chromosomes of the rainbow trout (Salmo gairdneri).

White-blood-cell culture was used to examine the chromosomes of 53 rainbow trout (Salmo gairdneri) from three locations in the Pacific Northwest of the United States. A Robertsonian chromosome polymorphism is present, resulting in diploid numbers of 60, 59, or 58 in different individuals with 104 chromosome arms. The low level of intraindividual Robertsonian variation, differences in the number of subtelocentric chromosomes between individuals with different chromosome numbers, and frequencies of fish with different chromosome numbers in one population suggest that the interindividual differences are inherited and not somatic. C-banding shows that constitutive heterochromatin is localized near the centromeres and near the secondary constriction one chromosome pair.