Ultrastructure of the centrometric regions of mouse chromosomes in metaphase chromosomes and interphase nuclei]

The chromatin ultrastructure was studied in the centromeric region of mitotic chromosomes and in interphase nuclei of mouse cells after differential staining on C-band. A new method is suggested to study centromeric region of chromosomes treated by the Giemsa banding technique. Fibers of chromosomes appeared to be packed denser in the centromeric regions of mitotic chromosomes than in arms. The disposition of chromatin fibers in the centromeric chromocentres of interphase nuclei is the same as in the centromeric regions of mitotic chromosomes.     

Characterization of different types of condensed chromatin inCostus (Zingiberaceae)

The chromatin structure of six diploids species ofCostus was analysed using conventional Giemsa staining, C-banding and DAPI/CMA fluorochromes. The interphase nuclei in all the species show an areticulate structure and the prophase chromosomes show large blocks of proximal condensed chromatin. After banding procedures, each chromosome exhibits only centromeric dot-like DAPI⁺/CMA^– C-bands whereas the satellites (one pair at each karyotype) are weakly stained after C-banding and show a DAPI^–/CMA⁺ fluorescence. Two chromocentres show bright fluorescence with CMA and weak staining after C-banding whereas the others chromocentres show only a small fraction of DAPI⁺ heterochromatin. These results were interpreted to mean that the greater part of the condensed chromatin has an euchromatic nature whereas two types of well localized heterochromatin occur in a small proportion. The Z-stage analysis suggests that heterochromatin and condensed euchromatin decondense at different times. The chromosome number and morphology of all species are given and the implications of the condensed euchromatin are discussed.Dedicated to Prof.Elisabeth Tschermak-Woess on the occasion of her 70th birthday.     

DNA loss during C-banding of chromosomes of Lilium longiflorum

Root tip chromosomes were uniformly labelled with ³H-thymidine and replicate squashes were made. One set was untreated, one incubated in Ba(OH)₂ solution, and a further set treated sequentially in Ba(OH)₂ and hot saline-citrate (2 × SSC) to reveal C-bands. All replicates were autoradiographed and comparative grain counts made. Differences in grain numbers per metaphase cell showed that Ba(OH)₂ extracted 40% of label, and that a further 23% was lost in the subsequent SSC incubation. The distribution of grains was mapped along a sample of each of five individually-recognisable chromosomes at the three treatment stages. Within each chromosome, the number of grains per segment did not differ significantly from a random distribution. This was true for all five chromosomes at all three stages of treatment, whether or not the regions were C-banded. — We conclude that DNA extraction occurs progressively during C-banding in Lilium, but that C-bands are not dark because of their relatively high retention of DNA.     

Orientation of interphase chromosomes as detected by Giemsa C-bands

The orientation of Giemsa C-bands has been studied in mitotic and interphase cells of Allium cepa, A. sativum and of Aloe vera. The C-bands in these three species are located at the telomeres, secondary constriction region of the nucleolar chromosomes and the centromeric regions, respectively. Observations in A. cepa and Aloe indicate clearly that the interphase chromosomes are non-random in their orientation and possibly maintain their telophase configuration through the attachment of telomeres and perhaps of kinetochores with the nuclear membrane. Electron micrographs of onion cells also reveal that certain heterochromatic segments are associated with the nuclear membrane. — The nucleolar interstitial C-bands in A. sativum remain free in the nucleoplasm and may come close to each other due to heterochromatic attraction. Such a heterochromatic attraction is also evident between telomeric regions and between centromeres. However, a two by two attachment could not be noticed. A diagrammatic representation of the orientation of interphase chromosomes has been presented.The major part of this work was presented at the First International Congress on Cell Biology, Boston, Sept. 5–10, 1976 (Platform Session 36, J. Cell Biol. 70, 418a (1976)     

Two types of constitutive heterochromatin in the chromosomes of some Fritillaria species

A Giemsa banding technique has been used to study C-banding in mitotic chromosomes in root tips of Fritillaria graeca, F. crassifolia and F. rhodocanakis, all diploids (2n=24) belonging to the graeca group. In the first two the C-bands were of two types, diverging in respect of staining regularly and specifically within chromosomes. In one type it was weak, being intermediate between that of intensely stained ones, representing the other class, and the euchromatin. In F. graeca the pale bands were proximally localized and confined to 5 pairs, whereas in F. crassifolia they occurred only in the 4 M chromosomes, in each within the centromeric constriction as a large inclusion. The interphase nuclei of both species contained pale and heavily stained chromocentres. No pale ones occurred in such nuclei of F. rhodocanakis. The probability is discussed that the two classes of C-band represent distinct types of heterochromatin, differing both in respect of condensation throughout the whole mitotic cycle and in the repetitive DNA sequences they most likely contain. In all 3 species pairs of Giemsa-positive centromeric dots, representing the centromeres, were masked both by proximally or centromerically localized bands, irrespective of the class of heterochromatin they represented.     

The reaction to c-banding of c-banded constituents during mitotic cycle ofCrepis capillaris

The reaction to C-banding was investigated throughout the mitotic cycle ofCrepis capillaris (2n=6): (1) 18–22 C-bodies or C-bands were found during mid telophase and interphase to prophase and metaphase, and also 12–14 at late anaphase to early telophase in the mitotic cycle. Fewer C-bands in late anaphase to early telophase were due to the absence of minute bands; (2) large and medium sized C-bands were strongly stained by Giemsa, while small and minute bands stained palely. It is suggested that inCrepis capillaris the difference of color in C-banded segments following Giemsa staining is referable to the amount of constitutive heterochromatin rather than to the difference in the condensation and decondensation; (3) the size of C-bodies changed during telophase to interphase and prophase. It is inferred that the extent of C-bodies is regulated by both the length of DNA sequences of constitutive heterochromatin and the amount of proteins combined with C-banded DNA. It was shown that the reaction to C-banding is neither due to the differential condensation of chromatin nor to a higher concentration of DNA in the C-banded regions, in the C-banding mechanism as has been suggested so far at least.     

Silver staining test of nucleolar suppression in the Lilium hybrid ‘Black Beauty’

Nucleolar organizing regions in mitotic chromosomes from Lilium longiflorum, L. henryi and L. speciosum, have been silver banded. Nucleoli in interphase cells were also silver stained. Silver banding and nucleolar counting in Lilium cv ‘Black Beauty’, a hybrid between L. speciosum and L. henryi, indicate that nucleolar suppression is not occurring.     

Late labelled regions in relation to Q- and C-bands in chromosomes of Lilium longiflorum and L. pardalinum

Root tips were pulse-labelled with tritiated thymidine. Late-labelled regions were mapped by quantitative autoradiography of metaphase chromosomes collected 11 h after the pulse for longiflorum (mean G₂=14 h), and 13 h for pardalinum (mean G₂=18 h). Late label in both species was preferentially located in sub-distal regions of the longer chromosome arms. Minimal labelling occurred in centromeric areas. — Some brightly Q-banded regions were late labelled, and some dull areas were not. However, late patterns were considerably more localised than bright Q-bands, and late regions were closely similar between species whereas Q-band patterns are not. Therefore bright Q-bands are apparently not consistently late replicating in Lilium, as they are in mammals, and they may therefore represent a different category of chromosomal substructure. — Centromeric C-bands and those at most nucleolar organisers were not late labelled. Only the more distal intercalary C-bands replicated late, and they were not significantly later than the chromatin surrounding them.     

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.     

Nucleolar behaviour in Triticum

The maximum number of major nucleoli (macronucleoli) per nucleus of hexaploid, tetraploid and diploid wheat, Aegilops speltoides and Ae. squarrosa corresponded to the number of satellited chromosomes of each species. Smaller nucleoli (micronucleoli) were rare or absent in all of these species except the hexaploid, in which they were predominantly organized on chromosome arm 5D^s. — Fewer than the maximum number of macronucleoli in a mitotic interphase nucleus resulted from fusion of developing nucleoli. Enforced proximity of nucleolus-organizing regions resulted in more frequent fusion of nucleoli. — Analyses of related interphase nuclei showed that nucleoli, and hence probably chromosomes, undergo limited movement during mitotic interphase. These observations also indicate that specific chromosomes do not occupy specific sites in the interphase nucleus.     

Giemsa banding of meiotic chromosomes

Applying a Giemsa staining technique to the meiotic chromosomes of Anemone blanda demonstrates that Giemsa bands similar to those seen in the mitotic chromosomes are discernible at all the principal stages of meiosis. The bands are not a product of the Giemsa procedure since they can be seen in unstained preparations using phase-contrast optics as chromocentres in interphase nuclei and as condensed regions in prophase chromosomes. That the bands seem to be permanent features of the nucleus, whether it is dividing or otherwise is an important consideration for understanding their nature and function. Bands and chiasmata do not coincide indicating on the one hand that chiasmata are not responsible for differences in banding patterns and on the other hand that the conservation of bands is an indication that they are either inert regions or specialised regions with considerable adaptive significance. These alternatives can only be resolved by genetical studies of the banding phenomena.     

Visualization of chromatin distribution in living PTO cells by Hoechst 33342 fluorescent staining

Chromatin distribution was visualized in living cells with the selective DNA fluorochrome Hoechst 33342. This dye was shown to be non-toxic on the rat kangaroo PTO cell line by measuring the labelled cell growth rate. The aim of this work was firstly to visualize chromatin distribution without fixation or dehydration and secondly to demonstrate that quantitative determination of DNA content was possible under these non-toxic labelling conditions. During interphase, condensed, decondensed and thin network chromatin configurations were visualized. In nucleolar regions the fluorochrome revealed well-defined chromocentres. During mitosis, fluorescent chromosome banding was observed in vital conditions and chromocentres on fixed chromosomes. Chromatin segregation was visualized after micronucleation, which induced chromosomal set distribution in individual micronuclei. By this means, we demonstrated that the chromocentres observed in interphase nuclei were part of nuclear organizer region (NOR)-bearing chromosomes. This vital staining of chromatin was shown to be compatible with the quantitative determination of DNA content, both in living PTO cells and in isolated nuclei.     

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.     

Chromatin arrangements in intact interphase nuclei examined by laser confocal microscopy

Using a laser confocal microscope, chromatin arrangements in intact interphase nuclei were investigated in four plant species. Chromosomes in these plants have specific segments that can be stained with the fluorescent dye chromomycin A₃ (CMA). We stained centromeres inHordeum vulgare, sub-telomeric regions inSecale cereale, satellites inChrysanthemum multicore, and the satellites and the short arms of chromosomes with satellites inHemerocallis middendorfii. The following points were shown: (1) In mitotic interphase nuclei, the centromere and the telomeres of both arms touched the nuclear membrane and had evident polarity. Some CMA-bodies in sub-telomeric regions do not contact the nuclear membrane. (2) Differentiated nuclei had a non-random construction. Polarity of chromosomes is maintained, however, the chromosomes are far apart from the nuclear membrane. (3) Associations in sub-telomeric regions in the interphase nuclei ofSecale cereale were probably due to the association of heterochromatic regions with identical repeated sequences rather than telomere associlations. (4) In interphase nuclei ofChrysanthemum multicore, satellites fused during interphase.     

Structural differentiation of the meiotic and mitotic chromosomes of the salamander,Ambystoma macrodactylum

The lampbrush chromosomes of the long-toed salamander, Ambystoma macrodactylum Baird, have been analysed and a map of the oocyte genome prepared. The location of C-bands and cold-induced-constrictions has been established in mitotic chromosomes and compared with the location of marker structures and chiasmata in several lampbrush bivalents. In the lampbrush chromosomes, C-bands are tentatively correlated with sphere-organizing loci and with regions of low chiasma frequency; cold-induced-constrictions are tentatively correlated with regions of high chiasma frequency. In general, in this salamander, C-bands do not coincide in position with cold-induced-constrictions. We have compared our results with those obtained by Callan (1966) in his investigation of chromosomes of the axolotl, Ambystoma mexicanum, and we present an analysis of the similarities and differences that are visible in the chromosome sets of these two ambystomatid species.     

Heterochromatin and chromosomal aberration in microtus agrestis: role of chromosomal association

Mitomycin C (MC) -induced chromatid aberrations among the chromosomes of Microtus agrestis are preferentially localized in the constitutive heterochromatic regions, i.e., major part of the sex chromosomes and the centromeric regions of the autosomes. In the sex chromosomes, intrachanges predominate, while interchanges between the two X chromosomes are very rare. This pattern of distribution of different types of aberrations is interpreted as due to the individual chromocentres that are formed by the two X chromosomes in the interphase.     

Changes of Chromosome Length and Constitutive Heterochromatin in Association with Cell Division during Early Development of Cynops pyrrhogaster embryo

The length of chromosomes in the presumptive ectoderms of Cynops embryos was measured at nine successive cell divisions from the 6th (cleavage stage) to the 14th (gastrula stage). Up to the 10th cell division (cleavage stage) the chromosome length remained constant. At the 11th cell division the chromosomes began to shorten and continued to shorten at every cell division up to the 14th cell division. The degree of shortening and the mode of variation in length corresponded to the respective developmental stages of cleavage, blastula and gastrula. During those periods when chromosomes became shortened, some fine C-bands of the paracentromeric region found in earlier stages fused together. The chromatin of interphase nuclei also showed considerable changes during chromosome shortening. Besides the size reduction of interphase nuclei, the number of C-band granules in an interphase nucleus decreased in parallel with chromosome shortening and fusion of C-bands in mitotic chromosome.     

Chromonema and chromomere

A study of ultrathin sections of normal Chinese hamster cells and cells treated with decreasing concentrations of bivalent cations (Ca²⁺ and Mg²⁺) in situ revealed several discrete levels of compaction of DNA-nucleoprotein (DNP) fibrils in mitotic chromosomes and the chromatin of interphase nuclei. At concentrations ranging from 3 mM CaCl₂ and 1 mM MgCl₂ to ten times less, the chromosomes are found to contain fibrous elements (chromonemata) about 100 nm in diameter. As Ca²⁺ concentration is gradually decreased to 0.2–0.1 mM, the chromosomes decondense into a number of discrete chromatin structures, the chromomeres. As decondensation proceeds, these chromomeres acquire a rosettelike structure with DNP fibrils radiating from an electron-dense core. Upon complete decondensation of chromosomes, individual chromomeres persist only in the centromeric regions. The following levels of DNP compaction in mitotic chromosomes are suggested: a 10-nm nucleosomal fibril, a 25-nm nucleomeric fibril, and the chromonema, a fibrous structure, about 100 nm in diameter, composed of chromomeres. Interphase nuclei also contain structures which are morphologically similar to the chromomeres of mitotic chromosomes.