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.     

Replication of autosomal heterochromatin in man

Summary In interphase nuclei of leukocytes and oral mucosa cells of normal human males and f males, two types of heterochromatin can he distinguished according to their location in the nucleus. Firstly, nucleolus-associated heterochromatin which consists of one large mass of autosomal segments surrounding the nucleolus, or several large masses if there appears to be more than one nucleolus in the same nucleus. Secondly, scattered heterochromatin composed of a large number of positively heteropycnotic bodies scattered throughout the nucleus and not directly associated with the nucleolus. The correspondence of this type of heterochromatin with chromosome segments is obtained at late prophase where several positively heteropycnotic regions belonging to the autosomes are found scattered throughout the nucleus.In human females sex-chromatin is present in addition to these two types. In leukocytes the sex-chromatin cannot be easily identified due to the large size and number of the scattered heterochromatic bodies, but in oral mucosa cells such a distinction is more easily achieved due to the smaller amount of autosomal heterochromatin.Nucleolus-associated and scattered heterochromatin from leukocytes of both sexes synthesized their DNA at a different period of time from the euchromatin. The asynchrony of replication observed in the heterochromatin at interphase is in agreement with the asynchrony between autosomes and within autosomes described by many authors at metaphase. This does not mean, however, that every segment or chromosome found replicating asynchronously at metaphase contains necessarily heterochromatin.Dedicated to Professor H. Bauer on the occasion of his 60th birthday. — This investigation was supported by a research grant to A. Lima-de-Faria from the Swedish Natural Science Research Council.     

DNS-Replikation und Morphologie der X-Chromosomen während der Syntheseperiode bei Microtus agrestis

X-chromosome behaviour of female Microtus agrestis in interphase nuclei with and without large chromocenters was examined in cultured epithelial and fibroblast cells. By means of pulse-labeling, the configuration of the X-chromosomes in these nuclei can be illustrated; staining with pararosaniline-methylgreen seems to be most suitable. According to the replication behaviour, three types of chromatin can be discerned in the X-chromosomes: early replicating euchromatin, late replicating sex chromatin, and very late replicating heterochromatin. In fibroblasts only the sex chromatin forms a single, small chromocenter; in epithelial cells both the sex chromatin and the remaining heterochromatin form large chromocenters. Both types of heterochromatin replicate their DNA in the condensed state. It seems likely that the late replicating segments of the X-chromosomes (sex chromatin and remaining heterochromatin) are condensed in every cell, but they may not always be configurated or even visible as typical chromocenters; these segments could be distributed over a wide range of compact to more or less diffuse superstructures.     

Polymorphic patterns of heterochromatin distribution in guinea pig chromosomes

The chromosome complement and patterns of heterochromatin distribution (as demonstrated by the DNA d-r method) were studied from three different guinea pigs. Karyotype analyses showed that one of the females had a heteromorphic sex pair formed by a submetacentric X chromosome and a subterminal X chromosome originated by a shortening of the short arm (x-chromosome). The heterochromatin was mainly found in the pericentromeric areas of the autosomes and X chromosomes and in the short arm of pair 7. The Y chromosome exhibited a degree of heterochromatinization different from that of pericentromeric areas.—The analysis of the heterochromatin distribution in the X chromosomes showed that the smaller size of the heteromorphic x-chromosoine was probably due to a lack of heterochromatin in its short arm. Moreover, two out of the three animals studied had a heteromorphic pattern of heterochromatinization in the pair 21 characterized by heterochromatinization of the pericentromeric area in one chromosome and almost complete heterochromatinization of the other homologue.—It is suggested that most of the heterochromatin disclosed by the DNA d-r method is formed by repetitious DNA; and that the Y chromosome and perhaps some autosome regions in guinea pigs are formed by a type of heterochromatin with properties different from those of the constitutive and facultative heterochromatin (intermediate heterochromatin).Supported in part by NIH Grant 5-501-RR05672-02 and by NIH contract 70-2299.     

Heterochromatin in cells derived from Aedes albopictus (Skuse) mosquito tissue culture

Results obtained with the DNA d-r method in cultured cells from A. albopictus show that this technique brings out the location of the kinetochore as well as the nucleolar associated heterochromatin. It is also speculated that the kinetochore heterochromatin may be involved in somatic pairing, in the attachment of chromosomes to the nuclear membrane and in chromosome breakage.     

Studies on polytene chromosomes of Smittia parthenogenetica (Chironomidae,Diptera)

In polytene chromosome II of Smittia parthenogenetica a heterochromatin insertion has been studied which is derived from a germ-line limited chromosome section (Bauer, 1970). This insertion is C-banding positive, late replicating, inactive in RNA synthesis, fluoresces brightly with quinacrine and is polytenized. After N-banding a major part of the heterochromatin insertion is N-banding negative, whereas in the centre of the insertion a N-banding positive body is present. The properties of the N-positive and N-negative parts of the inserted heterochromatin section are compared with the properties of the heterochromatin of Chironomus melanotus and Drosophila melanogaster. It is concluded that the heterochromatin insertion consists of two different heterochromatin types and it is discussed whether the N-banding positive part within the insertion represents a heterochromatin type which is underreplicated during polytenization.Dedicated to Professor Dr. Hans Bauer in honour of his 75th birthday on September 27, 1979     

Analysis of different banding patterns and late replicating regions in chromosomes of Allium cepa,A. sativum and A. nigrum

Different banding procedures and preferential Giemsa staining of late replicating DNA-rich regions were carried out in metaphase chromosomes of three species belonging to different sections of the genus Allium (A. cepa, A. sativum and A. nigrum). The banding, as well as the late replicating patterns were species-specific. The late replicating pattern proved to be, in all cases, the more detailed, and represented the highest percentage of the karyotype differentially stained. Lower percents of the karyotype positively stained were accounted for by C-banding, by modified C-banding and by N-banding. In A. cepa interphase nuclei the pattern of constitutive heterochromatin fitted well with that of late replicating DNA-rich regions, but the coincidence with that revealed by C-banding was only partial. This supports the suggestion that late replicating regions may be considered to be a special category of heterochromatin. On the other hand, it seems that not all C-banded material replicates at the end of the S phase. By the modified C-banding, stained centromere dots or small bands, as well as bands at the NORs are observed.     

Evolutionary dynamics of heterochromatin in the genome of <Emphasis Type="Italic">Dichotomius</Emphasis> beetles based on chromosomal analysis

We comparatively analyzed six Dichotomius species (Coleoptera: Scarabainae) through cytogenetic methods and mitochondrial genes sequencing in the aim to identify patterns of chromosomal evolution and heterochromatin differentiation in the group. The chromosomal data were accessed through the classical analysis of heterochromatin and mapping of high and moderately repeated DNAs (C ₀ t-1 DNA fraction). Mitochondrial data were obtained from nucleotide sequences of the cytochrome oxidase I (COI) and 16S rRNA genes. The heterochromatin distribution was conserved but revealed variability in the base pair richness and repetitive DNA content, and an intense turnover of heterochromatic associated sequences seems to have occurred during Dichotomius speciation. Specifically for D. bos, an interesting pattern was observed, indicating apparently the presence of heterochromatic sequences composed of low copy-number sequences. Moreover, highly conserved terminal/sub-terminal sequences that could act as a telomeric or telomere-associated DNA were observed. The heterochromatin diversification patterns observed in Dichotomius were not accomplished by the diversification of the species studied, which may be a consequence of the intense dynamics that drive the evolution of repeated DNA clusters in the genome. Finally our findings also suggest that the use of C ₀ t-1 DNA fraction represents a powerful, inexpensive and not time consuming tool to be applied in understanding heterochromatin and repetitive DNA organization.     

Studies of mammalian chromosome replication

Sister chromatids of metaphase chromosomes can be differentially stained if the cells have replicated their DNA semiconservatively for two cell cycles in a medium containing 5-bromodeoxyuridine (BrdU). When prematurely condensed chromosomes (PCC) are induced in cells during the second S phase after BrdU is added to the medium, the replicated chromosome segments show sister chromatid differential (SCD) staining. Employing this PCC-SCD system on synchronous and asynchronous Chinese hamster ovary (CHO) cells, we have demonstrated that the replication patterns of the CHO cells can be categorized into G₁/S, early, early-mid, mid-late, and late S phase patterns according to the amount of replicated chromosomes. During the first 4 h of the S phase, the replication patterns show SCD staining in chains of small chromosome segments. The amount of replicated chromosomes increase during the mid-late and late S categories (last 4 h). Significantly, small SCD segments are also present during these late intervals of the S phase. Measurements of these replicated segments indicate the presence of characteristic chromosome fragment sizes between 0.2 to 1.2 m in all S phase cells except those at G₁/S which contain no SCD fragments. These small segments are operationally defined as chromosome replicating units or chromosomal replicons. They are interpreted to be composed of clusters of molecular DNA replicons. The larger SCD segments in the late S cells may arise by the joining of adjacent chromosomal replicons. Further application of this PCC-SCD method to study the chromosome replication process of two other rodents, Peromyscus eremicus and Microtus agrestis, with peculiar chromosomal locations of heterochromatin has demonstrated an ordered sequence of chromosome replication. The euchromatin and heterochromatin of the two species undergo two separate sequences of decondensation, replication, and condensation during the early-mid and mid-late intervals respectively of the S phase. Similar-sized chromosomal replicons are present in both types of chromatin. These data suggest that mammalian chromosomes are replicated in groups of replicating units, or chromosomal replicons, along their lengths. The organization and structure of these chromosomal replicons with respect to those of the interphase nucleus and metaphase chromosomes are discussed.     

Possible role of H1 histone in replication timing

AT‐rich repetitive DNA sequences become late replicating during cell differentiation. Replication timing is not correlated with LINE density in human cells (Ryba et al. 2010). However, short and properly spaced runs of oligo dA or dT present in nuclear matrix attachment regions (MARs) of the genome are good candidates for elements of AT‐rich repetitive late replicating DNA. MAR attachment to the nuclear matrix is negatively regulated by chromatin binding of H1 histone, but this is counteracted by H1 phosphorylation, high mobility group proteins or, indirectly, core histone acetylation. Fewer MAR attachments correlates positively with longer average DNA loop size, longer replicons and an increase of late replicating DNA.     

Observations on centromeric heterochromatin and satellite DNA in salamanders of the genus Plethodon

DNA from Plethodon cinereus cinereus separates into two fractions on centrifugation to equilibrium in neutral CsCl. The smaller of these fractions has been described as a high-density satellite. It represents about 2% of nuclear DNA from this species, and it has a density of 1.728 g/cm³. It is cytologically localized near the centromeres of all 14 chromosomes of the haploid set. In P. c. cinereus the heavy satellite DNA constitutes about 1/4 of the DNA in centromeric heterochromatin. The nature of the rest of the DNA in centromeric heterochromatin is unknown. The number of heavy satellite sequences clustered around the centromeres in a chromosome from P. c. cinereus is roughly proportional to the size of the chromosome, as determined by in situ hybridization with satellite-complementary RNA, and autoradiography. Likewise the amount of contromeric heterochromatin, as identified by its differential stainability with Giemsa, shows a clear relationship to chromosome size. — The heavy satellite sequences identified in DNA from P. c. cinereus are also present in smaller amounts in other closely related forms of Plethodon. Plethodon cinereus polycentratus and P. richmondi have approximately half as many of these sequences per haploid genome as P. c. cinereus. P. hoffmani and P. nettingi shenandoah have about 1/3 as many of these sequences as P. c. cinereus. P. c. cinereus, P. c. polycentratus, and P. richmondii all have detectable heavy satellites with densities of 1.728 g/cm³. Among these forms, satellite size as determined by optical density measurements, and number of satellite sequences as determined from hybridization studies, vary co-ordinately. P. c. cinereus heavy satellite sequences are not detectable in P. nettingi, P. n. hubrichti, or P. dorsalis. The latter species has a heavy satellite with a density of 1.718 g/cm³, representing about 8% of the genomic DNA, and two light satellites whose properties have not been investigated. The heavy satellite of P. dorsalis is cytologically localized in the centromeric heterochromatin of this species. — These observations are discussed in relation to the function and evolution of highly repetitive DNA sequences in the centromeric heterochromatin of salamanders and other organisms.     

Molecular and cytological characteristics of nuclear DNA and chromatin for angiosperm systematics: DNA diversification in the evolution of four orchids

The species- and genus-specific DNA content, average base composition of nuclear DNA, presence or absence of satellite DNA, the percentage of heterochromatin and other characteristics of nuclear DNA and nuclear structure allow to deduce the molecular changes which accompanied, or more probably caused, cladogenesis in the orchids studied. It is suggested that saltatory replication (generative amplification) of certain DNA sequenes, diversification of reiterated DNA sequences, and loss of DNA play an important role in the evolution of orchids.—The relationship between changes of genome composition and of nuclear structure and ultrastructure is discussed on the basis of cot curves, heterochromatin staining with Giemsa (C banding), electron microscopy of nuclei, and molecular hybridization in situ.Some aspects of this paper have been presented at the Helsinki Chromosome Conference, August 1977 (Nagl & Capesius 1977).     

DNS-Reduplikationsmuster der Somatischen Chromosomen von Cricetus cricetus (L.)

The patterns of terminal DNA synthesis of the autosomes and sex chromosomes of Cricetus cricetus were studied. Characteristic late replicating segments are found on all chromosomes allowing identification of most autosomes. The sex chromosomes of both sexes behave similarly; in the male, half of the X and the entire Y are late replicating and heteropycnotic, in the female, half of one X and the whole of the other X. The isopycnotic part of the X-chromosome comprises about 5% of the haploid female complement.

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Wesentliche Teile der vorliegenden Arbeit werden von Fräulein Dorothee Hepp als Dissertation der Medizinischen Fakultät der Universität Freiburg i. Br. vorgelegt.

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Wir danken Dr. Susumu Ohno für kristiche des Munuskriptes und Fräulein Elke Faisst für ihre bei den experimentellen Arbeiten.     

Relationships between species ofLeymus,Psathyrostachys, andHordeum (Poaceae,Triticeae) inferred from Southern hybridization of genomic and cloned DNA probes

We have used total genomic DNA as a probe to size-fractionated restriction enzyme digests of genomic DNA from a range ofTriticeae species from the generaLeymus Hochst.,Psathyrostachys Nevski, andHordeum L., and hybrids betweenHordeum andLeymus to investigate their taxonomic relationships. Genomic Southern hybridization was found to be an effective and simple way to assess the distribution and diversity of essentially species-specific and common, repetitive DNA sequences, and is hence especially useful in evolutionary studies. The DNA sequences ofH. vulgare seem to diverge substantially from those ofH. brachyantherum, H. lechleri, H. procerum, andH. depressum. The genome ofThinopyron bessarabicum shows little homology to those of theLeymus species investigated, confirming thatT. bessarabicum is not an ancestral genome inLeymus. Although the genomes ofLeymus andPsathyrostachys share substantial proportions of DNA sequences, they include divergent repeated sequences as well. Hybridization with a ribosomal DNA probe (pTa 71) showed that the coding regions containing structural genes encoding the 18 S, 5.8 S, and 26 S ribosomal RNA were conserved among the species investigated, whereas the intergenic spacer region was more variable, presenting different sizes of restriction fragments and enabling a classification of the species. The rye heterochromatin probe pSc 119.2 hybridized to DNA fromH. lechleri andT. bessarabicum, but not to DNA from the other species investigated.     

An autoradiographic study of the chromosomes of the rat,with special regard to the sex chromosomes

The pattern of terminal DNA synthesis of rat chromosomes was studied by means of tritiated thymidine incorporation and autoradiography. In the female, an entire X-chromosome underwent relative out-of-phase replication. In the male, the Y-chromosome showed a remarkable late replication. Several pairs of autosomes exhibited characteristic replicating patterns which were useful for their identification. The relation between the less prominent out-of-phase replication of the late replicating X-chromosome and the difficulty in finding the sex dimorphism of interphase nuclei of the rat is discussed.Contribution No 710 from the Zoological Institute, Faculty of Science, Hokkaido University, Sapporo.One of the authors, S. Makino, is much delighted to dedicate this paper to Professor Dr. J. Seiler in celebration of his 80th anniversary, on the 16th May, 1966.     

Aberrant replication timing induces defective chromosome condensation in Drosophila ORC2 mutants

Background: The accurate duplication and packaging of the genome is an absolute prerequisite to the segregation of chromosomes in mitosis. To understand the process of cell-cycle chromosome dynamics further, we have performed the first detailed characterization of a mutation affecting mitotic chromosome condensation in a metazoan. Our combined genetic and cytological approaches in Drosophila complement and extend existing work employing yeast genetics and Xenopus in vitro extract systems to characterize higher-order chromosome structure and function.Results: Two alleles of the ORC2 gene were found to cause death late in larval development, with defects in cell-cycle progression (delays in S-phase entry and metaphase exit) and chromosome condensation in mitosis. During S-phase progression in wild-type cells, euchromatin replicates early and heterochromatin replicates late. Both alleles disrupted the normal pattern of chromosomal replication, with some euchromatic regions replicating even later than heterochromatin. Mitotic chromosomes were irregularly condensed, with the abnormally late replicating regions of euchromatin exhibiting the greatest problems in mitotic condensation.Conclusions: The results not only reveal novel functions for ORC2 in chromosome architecture in metazoans, they also suggest that the correct timing of DNA replication may be essential for the assembly of chromatin that is fully competent to undergo mitotic condensation.     

Replication banding patterns in the spined loach,Cobitis taenia L. (Pisces,Cobitidae)

The chromosomal complement of Cobitis taenia was analysed by replication banding techniques to determine whether there were specific patterns that could allow distinction of the different chromosomes. The diploid chromosome number of 2n = 48 is diagnostic of this species. In vivo 5-bromodeoxyuridine (5-BrdU) incorporation induced highly reproducible replication bands. Most of the chromosome pairs were distinguishable on the base of their banding patterns. The karyotype, consisting of five pairs of metacentrics, nine pairs of submetacentrics and 10 pairs of subtelocentrics and acrocentrics, was confirmed. C-banding and replication banding patterns were compared, and heterochromatin was both early and later replicating. C-positive heterochromatin in centromeric regions was mainly early replicating, but that located in pericentromeric regions was late replicating. Most of the late-replicating regions found interstitially were C-band negative. The results obtained so far for combined chromosomal staining methods of C. taenia and other Cobitis fish species are discussed.     

Quantitative variation of “Mus musculus-like” constitutive heterochromatin and satellite DNA-sequences in the genus Mus

The extent of conservation of constitutive heterochromatin in three species of Mus viz. M. musculus, M. booduga and M. dunni, with shared cytological properties and homologous DNA sequences has been studied. The cytological properties were investigated by doing fluorescence staining and condensation inhibition of their chromosomes with Hoechst 33258. Both the parameters indicate the occurrence of a reduced quantum of M. musculus like heterochromatin at specific sites in the other two genomes. In situ hybridization of the nick translated ³H-labelled M. musculus satellite DNA with M. booduga and M. dunni chromosomes, also corroborates our Hoechst 33258 findings and comparable variation in the amount and site of occurrence of sequences homologous to M. musculus satellite DNA in these species are noticed. The study thus provides a good example of a gradual quantitative variation of a particular type of heterochromatin and in turn of the repetitive DNA constituting it in different related species. Further since the heterochromatin in M. booduga and M. dunni is expected to contain different repetitive DNA sequences in addition to those homologous to M. musculus satellite DNA, it is proposed that a change in the balance between two or more repetitive sequences in heterochromatin may be more crucial in its evolutionary consequences rather than a mere increase or decrease of a homogeneous repetitive sequence.     

Studies of He-T DNA sequences in the pericentric regions of Drosophila chromosomes

He-T DNA is a complex set of repeated DNA sequences with sharply defined locations in the polytene chromosomes of Drosophila melanogaster. He-T sequences are found only in the chromocenter and in the terminal (telomere) band on each chromosome arm. Both of these regions appear to be heterochromatic and He-T sequences are never detected in the euchromatic arms of the chromosomes (Young et al. 1983). In the study reported here, in situ hybridization to metaphase chromosomes was used to study the association of He-T DNA with heterochromatic regions that are under-replicated in polytene chromosomes. Although the metaphase Y chromosome appears to be uniformly heterochromatic, He-T DNA hybridization is concentrated in the pericentric region of both normal and deleted Y chromosomes. He-T DNA hybridization is also concentrated in the pericentric regions of the autosomes. Much lower levels of He-T sequences were found in pericentric regions of normal X chromosomes; however compound X chromosomes, constructed by exchanges involving Y chromosomes, had large amounts of He-T DNA, presumably residual Y sequences. The apparent co-localization of He-T sequences with satellite DNAs in pericentric heterochromatin of metaphase chromosomes contrasts with the segregation of satellite DNA to alpha heterochromatin while He-T sequences hybridize to beta heterochromatin in polytene nuclei. This comparison suggests that satellite sequences do not exist as a single block within each chromosome but have interspersed regions of other sequences, including He-T DNA. If this is so, we assume that the satellite DNA blocks must associate during polytenization, leaving the interspersed sequences looped out to form beta heterochromatin. DNA from D. melanogaster has many restriction fragments with homology to He-T sequences. Some of these fragments are found only on the Y. Two of the repeated He-T family restriction fragments are found entirely on the short arm of the Y, predominantly in the pericentric region. Under conditions of moderate stringency, a subset of He-T DNA sequences cross-hybridizes with DNA from D. simulans and D. miranda. In each species, a large fraction of the cross-hybridizing sequences is on the Y chromosome.