Chromosome banding in Amphibia

The distribution and quantity of constitutive heterochromatin and of the nucleolus organizer regions (NORs) on the chromosomes of 22 species of bufonids and hylids (Amphibia, Anura) was investigated. Three different kinds of constitutive heterochromatin were found and the frequency of brightly fluorescing heterochromatic regions was remarkably high. On almost all chromosomes there is centric and telomeric heterochromatin. Quantitative estimates of heterochromatin demonstrate that large DNA differences among closely related species can not be attributed to differing quantities of constitutive heterochromatin. In all species investigated, only one homologous pair of NORs was found, which lies preferentially in the proximal and interstitial segments of the long chromosome arms. The NORs are always associated with constitutive heterochromatin on both sides. The size variability between homologous NORs is very high. In the euchromatic regions of the metaphase chromosomes, neither Q- nor G-bands can be demonstrated; this can be attributed to an extremely strong contraction of the anuran chromosomes. On the basis of these results various mechanism of the chromosomal evolution in Anura are discussed.     

Unordered arrangement of chromosomes in the nuclei of chicken spermatozoa

The arrangement of chromosomes in the elongated sperm nuclei of chicken was studied using fluorescence in situ hybridization with probes specific for telomeres of all chromosomes, a microchromosome, the long arm of chromosome 6, the large heterochromatic block on the Z-chromosome, and the same heterochromatic block plus subtelomeric sites on macrochromosomes 1–4. The positions of all probes vary from one sperm to another. No order in chromosome arrangement is apparent. It is suggested that large chromosome size and small chromosome number correlate with constant positions of chromosomes and vice versa. Based on the known quantity of repetitive units of the repeat on the Z-chromosome, the degree of compaction of chromatin in the chicken sperm nucleus is estimated as ca 0.7 Mb/μm. As judged from the length of the heterochromatic region of the Z-chromosome at the lampbrush stage, the total length of the Z-chromosome in mature sperm is 2.5–4 times that of the sperm nucleus. Received: 15 December 1997; in revised form: 24 March 1998 / Accepted: 14 April 1998     

Determinants of sperm nuclear shaping in the genus Xenopus

The morphogenesis of sperm nuclei was investigated in six different species or subspecies of the genus Xenopus (Pipidae, Anura). The sequence of nuclear morphogenesis was similar in each species used in this study. Electrophoretic comparison of the basic chromatin proteins from late spermatids and sperm of each species demonstrated that the complements of histones and spermatid-sperm-specific basic proteins were extremely diverse suggesting that shape was not determined by specific basic proteins or mechanisms of histone removal. This conclusion was reinforced by the observation that Xenopus sperm DNA decondensed by 2.0 M NaCl remained contrained in residual structures which resembled intact sperm nuclei. These observations suggested that morphogenesis of sperm nuclei is directed by proteins or RNA molecules which are not directly responsible for chromatin condensation.     

Ordered arrangement and rearrangement of chromosomes during spermatogenesis in two species of planarians (Plathelminthes)

The pattern of distribution of telomeric DNA (TTAGGG), 28S rDNA, and 5S rDNA has been studied using fluorescence in situ hybridization (FISH) and primed in situ labelling during spermatogenesis and sperm formation in the filiform spermatozoa of two species of planarians, Dendrocoelum lacteum and Polycelis tenuis (Turbellaria, Plathelminthes). In both species, the positions of FISH signals found with each probe sequence are constant from cell to cell in the nuclei of mature sperm. Chromosome regions containing 5S and 28S rDNA genes are gathered in distinct bundles of spiral form. In early spermatids with roundish nuclei, the sites of a given sequence on different chromosomes remain separate. Centromeres (marked by 5S rDNA) gather into a single cluster in the central region of the slightly elongated sperm nucleus. During spermatid maturation, this cluster migrates to the distal pole of the nucleus. In Polycelis, telomeric sites gather into three distinct clusters at both ends and in the middle of the moderately elongated nucleus. These clusters retain their relative positions as the spermatid matures. All the chromosome ends bearing 28S rDNA gather only into the proximal cluster. Our data suggest that structures in the nucleus selectively recognise chromosome regions containing specific DNA sequences, which helps these regions to find their regular places in the mature sperm nucleus and causes clustering of the sites of these sequences located on different chromosomes. This hypothesis is supported by observations on elongated sperm of other animals in which a correlation exists between ordered arrangement of chromosomes in the mature sperm nucleus and clustering of sites of the same sequence from different chromosomes during spermiogenesis. Received: 15 December 1997; in revised form: 24 March 1998 / Accepted: 14 April 1998     

Non-isotopic detection of chromosome 1 in human meiosis and demonstration of disomic sperm nuclei

Summary Nonradioactive in situ hybridization with the biotin-labeled chromosome 1-specific probe pUC1.77 was performed on human mitotic and meiotic chromosomes, and on sperm nuclei. The streptavidine-horseradish-peroxidase and diaminobenzidine detection system demonstrated heteromorphisms in the Iq12 heterochromatic region, not only in mitotic cells but also in mature sperm heads. The localization of chromosome 1 could be traced through all meiotic stages and in the sperm nuclei. The frequency of chromosome 1 disomy in human sperm, as indicated by two distinct hybridization signals, was calculated to be 0.41%.     

Chromosome banding in amphibia

The chromosomes of 26 species of Anura from variously highly evolved groups were analysed with the fluorescent GC-specific antibiotics mithramycin and chromomycin A₃ as well as with the AT-specific quinacrine. The mithramycin- and chromomycin A₃-stainings generally resulted in a pattern of the constitutive heterochromatin opposite to the one obtained with quinacrine stain. The weaker a heterochromatic region fluoresces with quinacrine, the stronger is the intensity of the fluorescence achieved with mithramycin and chromomycin A₃. Some of the telomeric and interstitial heterochromatic regions, however, exhibit no enhanced fluorescence with any of the fluorochromes. The nucleolar constrictions of the nucleolus organizer regions (NORs) displayed the brightest mithramycin- and chromomycin A₃-fluorescence in the karyotypes and interphase nuclei of all species examined. The contrast of the brightly fluorescing GC-rich heterochromatin and of the NORs is considerably enhanced, when the non-fluorescent AT-specific oligopeptide distamycin A is employed as a counterstain. No banding patterns were observed with the fluorochromes in the euchromatic regions of the metaphase chromosomes; this is attributed to the strong spiralization of the anuran chromosomes. A cytochemical classification of the various chromatin types in the anuran chromosomes is discussed on the basis of the differential labelings found on the constitutive heterochromatin by means of the fluorochromes.This paper is dedicated to Professor Dr. Hans Bauer on the occasion of his 75th birthday     

Morphological changes of sperm nuclei during spermatogenesis in the brown alga Cystoseira hakodatensis (Fucales, Phaeophyceae)

Morphological changes and chromatin condensation of sperm nuclei were observed during spermatogenesis in the fucalean brown alga Cystoseira hakodatensis (Yendo) Fensholt. Ultrastructural studies have shown that the mature spermatozoid has an elongated and concave nucleus with condensed chromatin. The morphological changes and the chromatin condensation process during spermatogenesis was observed. Nuclear size decreased in two stages during spermatogenesis. During the first stage, spherical nuclei decreased in size as they were undergoing meiotic divisions and the subsequent mitoses within the antheridium. During the second stage, the morphological transformation from a spherical into an elongated nucleus occurred. Afterwards, chromatin condensed at the periphery in each nucleus, and chromatin‐free regions were observed in the center of the nucleus. These chromatin‐free regions in the center of nucleus were compressed by the peripheral chromatin‐condensed region. As the result, the elongated and concave nucleus of the mature sperm consisted of uniformly well‐condensed chromatin.     

Specific arrangement of chromosomes in the spermiogenesis of Gallus domesticus

On the chromosomes of the rooster the constitutive heterochromatin (C-bands) is to be found for the most part at the centromeres. The position of the centric heterochromatin in spermatids and sperm is not randomly distributed. In early, round spermatids one heterochromatic block lies at this exact position on the membrane that develops into the tip of the sperm nucleus (acrosomal chromocenter). During the elongation of the spermatid nucleus another heterochromatic block comes to lie on the basal nuclear membrane. The other centromeres arrange themselves tandem-wise between the acrosomal and the basal chromocenters. Comparisons have been made between this specific arrangement and the location of chromosomes in the sperm of amphibians and mammalians.     

Distamycin A/DAPI staining of heterochromatin in male meiosis of man

The sequential staining with distamycin A/DAPI provides an ideal method for studying the behaviour of heterochromatic regions in human male meiosis. The various meiotic and postmeiotic stages were found to have different staining qualities. Although all heterochromatic regions in human pachytene cells show specific DA/DAPI fluorescence, bright and clearly stained heterochromatic blocks can be distinguished from small DA/DAPI spots. Pachytene nuclei exhibit associations between heterochromatic regions of non-homologous bivalents. The heterochromatin of bivalent 9 generally presents as a cluster of small, discrete bodies. The heterochromatic regions of chromosomes 1, 9, 15, 16 and Y are preferentially stained at diakinesis and metaphase of the second meiotic division. The specific DA/DAPI staining disappears with the progressive volume reduction of middle and late spermatid nuclei. The heterochromatin of the chromatids fuses to form a large chromocenter during spermatid differentiation.     

Chromosomal constitution of nucleolus-associated chromatin in man

Summary Use of specific stains permits analysis of the frequency of nucleolus-associated heterochromatin in chromosomes 1 and 9 from human fibroblasts. In 81% of interphase nuclei the heterochromatic segment of both No. 1 chromosomes is associated with the nucleolus, while in 19% only one heterochromatic segment shows such an association with the other occupying a random position in the nucleoplasm. The nucleolar association of chromosome 9 heterochromatin is less constant: in 42.3% of the nuclei both segments are associated with the nucleolus, in 39% of the nuclei only one heterochromatic segment presents such an association, and in 18.7% neither of the two heterochromatic segments is in nucleolar association. In 6% of the cells, one or two chromosome 9 heterochromatic segments are in contact with the nuclear membrane.In situ hybridization using tritium-labeled 28S and 18S RNA shows that in the interphase nucleus the acrocentric short arms, carriers of ribosomal cistrons, are associated with the nucleolus.These observations demonstrate the complexity of the nucleolus-associated chromatin which, in addition to segments of chromosomes 1, 9, 13, 14, 15, 21 and 22, may include the Y chromosome. They also confirm that the nucleolus constitutes one of the orientation points determining the relative localization of chromosomes in the interphase nucleus.     

Occurrence of Mitochondria in the Nuclei of Tobacco Sperm Cells

Tobacco sperm cells contain intact mitochondria within their nuclei with a frequency of 0.35 [plusmn] 0.13 per cell. These inclusions appear to originate from mitochondria found among chromatids in the highly elongated metaphase plate of the dividing generative cell. These organelles are apparently captured during the reconstitution of the nuclear envelope. Only sperm cells were observed to contain these nuclear mitochondria; generative cells, vegetative pollen cells, transmitting tissue cells, unfertilized egg cells, and central cells lacked them. Nuclear mitochondria were also seen in the nuclei of the egg and central cell after fusion with sperm nuclei, suggesting that nuclear mitochondria are transmitted into the zygote and primary endosperm cells during double fertilization. Organellar inclusions in the sperm nucleus provide a potential mechanism for transmitting organellar DNA into the next generation and could potentially facilitate the transfer of genetic material between the nucleus and other organelles.     

Proteolysis of somatic type histones in transforming rat spermatid chromatin

Elongated rat spermatid nuclei have been isolated on the basis of their resistance to sonication in 0.32 M sucrose containing 1.5 mM CaCl₂. Chemical analyses indicate that approx. 35% of the DNA in these nuclei is associated with somatic type histones, while the remainder represents sperm histone-DNA complex. In contrast to nuclei of somatic cells, when elongated spermatid nuclei are incubated under appropriate conditions, somatic type histones but not sperm histone are rapidly degraded. Differential extraction of elongated spermatid nuclei with 5 mM HCl and then with various concentrations of NaCl followed by 0.2 M HCl has revealed that they contain two kinds of proteases. The protease in the 5 mM HCl extract is acrosin (EC 4.3.21.10). Rapid degradation of somatic type histones is, however, observable upon incubation of elongated spermatid nuclei which have been treated with 5 mM HCl and are therefore free of acrosin or upon incubation of elongated spermatid chromatin where the majority of acrosin is removed, suggesting that the observed proteolysis of somatic type histone is not due to acrosin. Proteases which may represent the enzymes responsible for the histone degradation are extractable from acrosin-free spermatid nuclei with NaCl (0.9 M) and by subsequent treatment of the salt-extracted nuclei with 0.2 M HCl. The proteases in the NaCl and the 0.2 M HCl extract possess identical properties and appear to be the same enyzyme which may exist in spermatid chromatin in two different forms.     

Higher-order genome organization in platypus and chicken sperm and repositioning of sex chromosomes during mammalian evolution

In mammals, chromosomes occupy defined positions in sperm, whereas previous work in chicken showed random chromosome distribution. Monotremes (platypus and echidnas) are the most basal group of living mammals. They have elongated sperm like chicken and a complex sex chromosome system with homology to chicken sex chromosomes. We used platypus and chicken genomic clones to investigate genome organization in sperm. In chicken sperm, about half of the chromosomes investigated are organized non-randomly, whereas in platypus chromosome organization in sperm is almost entirely non-random. The use of genomic clones allowed us to determine chromosome orientation and chromatin compaction in sperm. We found that in both species chromosomes maintain orientation of chromosomes in sperm independent of random or non-random positioning along the sperm nucleus. The distance of loci correlated with the total length of sperm nuclei, suggesting that chromatin extension depends on sperm elongation. In platypus, most sex chromosomes cluster in the posterior region of the sperm nucleus, presumably the result of postmeiotic association of sex chromosomes. Chicken and platypus autosomes sharing homology with the human X chromosome located centrally in both species suggesting that this is the ancestral position. This suggests that in some therian mammals a more anterior position of the X chromosome has evolved independently.     

Cytogenetic analysis of chromosome segments containing radiosensitivity genes in Drosophila. Radiation mutagenesis in the 44-45 region of chromosome 2 of Drosophila melanogaster

The first step of cytogenetic analysis of Drosophila melanogaster chromosome 2 44F-45D containing the radiosensitivity gene rad(2)201 is described. Using various mutation selection systems as well as lines of different origin and two kinds of ionizing radiation--gamma-rays and neutrons--the mutagenesis in the region of interest is characterized at the cytogenetic level. 85 gamma-induced mutations affecting viability were isolated in the 44F 2-4; 45C6-7 interval, 27% of mutations being chromosomal aberrations. 15 radiation-induced aberrations were obtained by selecting mutations at the white gene inserted into the 45D region by P-mediated transformation. The 44F-45D region is characterized by relatively low frequency of deficiency formation and by significant predomination of heterochromatic aberrations in the spectrum of rearrangements. In these regions, the existence of hot spots for heterochromatic aberrations was discovered. As low deletion frequency is not connected with the presence of haplolethal and haplosterile loci in the region studied, the unusual character of radiation mutagenesis reflects possibly the peculiarities in sequence organization of the chromosomal region mentioned or the packaging in the sperm nuclei.     

The murine heterochromatin protein M31 is associated with the chromocenter in round spermatids and Is a component of mature spermatozoa

In mature sperm the normal nucleosomal packaging of DNA found in somatic and meiotic cells is transformed into a highly condensed form of chromatin which consists mostly of nucleoprotamines. Although sperm DNA is highly condensed it is nevertheless packaged into a highly defined nuclear architecture which may be organized by the heterochromatic chromocenter. One major component of heterochromatin is the heterochromatin protein 1 which is involved in epigenetic gene silencing. In order to investigate the possible involvement of heterochromatin protein in higher order organization of sperm DNA we studied the localization of the murine homologue of heterochromatin protein 1, M31, during chromatin reorganization in male germ cell differentiation. Each cell type in the testis showed a unique distribution pattern of M31. Colocalization to the heterochromatic regions were found in Sertoli cells, in midstage pachytene spermatocytes, and in round spermatids in which M31 localizes to the centromeric chromocenter. M31 cannot be detected in elongated spermatids or mature spermatozoa immunocytologically, but could be detected in mature spermatozoa by Western blotting. We suggest that M31, a nuclear protein involved in the organization of chromatin architecture, is involved in higher order organization of sperm DNA.     

Flow cytometry of DNA in mouse sperm and testis nuclei.

Mutations that occur in spermatogenic cells may be expressed as changes in DNA content, but developmentally-dependent alteration of its staining properties complicates the quantitation fo DNA in individual germ cells. These alterations have been studied with flow cytometric techniques. Nuclei from mouse testis cells and sperm were stained by the acriflavine-Feulgen method. The fluorescence intensity frequency distribution of nuclei of testis cells was characterized by 2 major and 5 minor peaks. Nuclei sorted from the various peaks with a fluorescence-activated cell sorter were identified microscopically. These data were confirmed by generation of peaks with nuclei prepared from cell suspensions enriched in specific cell types. One of the major peaks corresponded to round spermatid nuclei. The other major peak, located at 0.6 of the fluorescence intensity of the round nuclei, corresponded to elongated spermatid nuclei. Purified nuclei of epididymal and vas deferens spermatozoa displayed asymmetric fluorescence distributions. A minor peak at 0.8 the intensity of the round spermatid nuclei was tentatively assigned to elongating spermatids. 2 of the minor peaks, located at 1.7 and 2.0 times the fluorescence intensity of the round nuclei, corresponded to clumps of 2 haploid and diploid nuclei. The additional peaks, located at 3.0 and 3.7 times the fluorescence intensity of round spermatid nuclei correspond to leptotene and zygotene spermatocytes and to late pachytene spermatocytes, respectively. These peaks contained clumps of nuclei. The homogeneity of the nuclei sorted from the peaks, as well as the relative sizes of the peaks, was enhanced when the nuclei were prepared from cells enriched in specific stages of development. The relative fluorescence intensities of the various testis nuclei were characteristic and repeatedly found but were not stoichiometric with the DNA content of the nuclei.     

Distamycin A/DAPI bands and the effects of 5-azacytidine on the chromosomes of the chimpanzee, Pan troglodytes

The chromosomes of the chimpanzee were stained with distamycin A/DAPI, which labels specific C-bands. Bright distamycin A/DAPI fluorescence was found in the heterochromatic regions of chromosomes 6, 11, 14 to 16, 18 to 20, and 23 and the Y. Lymphocyte cultures from chimpanzees were treated with low doses of 5-azacytidine during the last hours of culture. This cytosine analog induces highly distinct undercondensations in 28 heterochromatic regions of 19 chromosomes. These 5-azacytidine-sensitive regions are predominantly located in the terminal C-bands of the chromosomes. In vitro treatment with 5-azacytidine also preserves into the metaphase stage somatic pairings between the 5-azacytidine-sensitive heterochromatic regions in interphase nuclei. The homologies and differences regarding the chromosomal localization of distamycin A/DAPI-bright C-bands, 5-azacytidine-sensitive heterochromatin, 5-methylcytosine-rich DNA sequences, and satellite DNAs in the chimpanzee and man are discussed.