Mutability of constitutive heterochromatin (C-bands) during eukaryotic chromosomal evolution and their cytological meaning.

A quantitative analysis of the alterations of constitutive heterochromatin in eukaryotic chromosomal evolution was attempted using the accumulated C-banding data available for mammals, amphibians, fish, ants, grasshoppers, and plants. It was found that these eukaryotes could be classified into two types by their C-banding patterns: 1) Type I included mammals, fish, and ants, and 2) Type II included amphibians, grasshoppers, and plants. C-bands were rather scarce in Type I eukaryote chromosomes and were found around the pericentromeric region when present at all, whereas the predominance of interstitial or terminal C-bands was found in Type II eukaryote chromosomes. The Type I and II C-banding patterns can best be interpreted by assuming that in the former group of eukaryotes the saltatory increase in constitutive heterochromatin occurs preferentially at the pericentromeric regions of telocentric chromosomes induced by centric fission, with C-bands being eliminated almost completely by centric fusion and/or pericentric inversion. On the other hand, C-bands appear in the Type II eukaryotes both interstitially and in the telomeric regions of chromosomes, and there may be no effective mechanism to eliminate these bands once they are integrated.     

The organization of DNA in the mitotic and polytene chromosomes of Sciara coprophila

The organization of DNA in the mitotic metaphase and polytene chromosomes of the fungus gnat, Sciara coprophila, has been studied using base-specific DNA ligands, including anti-nucleoside antibodies. The DNA of metaphase and polytene chromosomes reacts with AT-specific probes (quinacrine, DAPI, Hoechst 33258 and anti-adenosine) and to a somewhat lesser extent with GC-specific probes (mithramycin, chromomycin A₃ and anticytidine). In virtually every band of the polytene chromosomes chromomycin A₃ fluorescence is almost totally quenched by counterstaining with the AT-specific ligand methyl green. This indicates that GC base pairs in most bands are closely interspersed with AT base pairs. The only exceptions are band IV-8A3 and the nucleolus organizer on the X. In contrast, quinacrine and DAPI fluorescence in every band is only slightly quenched by counterstaining with the GC-specific ligand actinomycin D. Thus, each band contains a moderate proportion of AT-rich DNA sequences with few interspersed GC base pairs. — The C-bands in mitotic and polytene chromosomes can be visualized by Giemsa staining after differential extraction of DNA and those in polytene chromosomes by the use of base-specific fluorochromes or antibodies without prior extraction of DNA. C-bands are located in the centromeric region of every chromosome, and the telomeric region of some. The C-bands in the polytene chromosomes contain AT-rich DNA sequences without closely interspered GC base pairs and lack relatively GC-rich sequences. However, one C-band in the centromeric region of chromosome IV contains relatively GC-rich sequences with closely interspersed AT base pairs. — C-bands make up less than 1% of polytene chromosomes compared to nearly 20% of mitotic metaphase chromosomes. The C-bands in polytene chromosomes are detectable with AT-specific or GC-specific probes while those in metaphase chromosomes are not. Thus, during polytenization there is selective replication of highly AT-rich and relatively GC-rich sequences and underreplication of the remainder of the DNA sequences in the constitutive heterochromatin.     

Restrictive localization of centromeric heterochromatin (C-bands) in Presbytis e. entellus (Dufresne) as compared to Macaca mulatta (Zimmerman)

C-bands are observed in the centromeric regions of only three pairs of autosomes and the distal portion of the small acrocentric Y in a total complement of 44 chromosomes of a male Presbytis e. entellus. Simultaneously treated slides of a Rhesus monkey, however, have C-bands in all the 42 chromosomes. The lack of C-bands may be due to (1) absence of highly repetitive DNA in the centromeric region of certain chromosomes or (2) presence of minute quantity of such DNA which is imperceptible or (3) different types of centromeric heterochromatin with a varying degree of repetition of DNA sequences all of which do not react in similar manner to various techniques employed at present. It is hypothesized that the centromeric heterochromatin rich in satellite DNA helps in withstanding the force of excessive coiling of chromosomes at the centromere to facilitate the functioning of the genes for microtubular protein during cell division when other genes are rendered inactive due to compactness of chromosomes.     

Different replication patterns of chromocentres and C-bands inLilium henryi

To determine if interphase chromocentres are fully equivalent to mitotic C-bands in plants, their times of replication have been compared in the large genome (1C=35 pg) ofLilium henryi. Nuclei of the root-tip cortex were pulse labelled with³H-thymidine and labelling patterns carefully followed in semi-thin sections during a 12 h chase period. Chromocentres decondense and replicate in the later stages of S-phase, after euchromatin has completed its replication. Late-replicating regions, reflecting a portion of the chromocentric material, were then mapped in mitotic chromosomes and found to be localized to the sub-distal and distal regions of all long chromosome arms. Most of the chromatin in these regions is non C-banded and, further, not all C-bands are located here. Some of the 11 inter-calary and 2 nucleolar C-bands are found in earlier replicating regions, as are the 12 centric bands. ThereforeLilium C-bands do not all replicate at the end of S-phase. Chromocentres occupy 17–18% of interphase nuclear volume while C-bands make up only 3.7% of the area of mitotic chromosomes. We conclude thatLilium chromocentres contain much other chromatin in addition to C-bands, and therefore that chromocentres and C-bands cannot be universally equated.     

The characteristics of karyotype and telomeric satellite DNA sequences in the cricket, Gryllus bimaculatus (Orthoptera, Gryllidae)

The chromosomes derived from the Japanese population of Gryllus bimaculatus were characterized by C-banding and Ag-NOR staining. The chromosome number, 2n = 28 + XX (female)/XO (male), corresponded with that of other populations of G. bimaculatus, but the chromosome configuration in idiograms varied between the populations. NORs were carried on one pair of autosomes and appeared polymorphous. The positive C-bands located at the centromere of all chromosomes and the distal regions of many chromosome pairs, and the size and the distribution pattern of the distal C-heterochromatin showed differences among the chromosomes. In addition, this paper reports on the characteristics of HindIII satellite DNA isolated from the genome of G. bimaculatus. The HindIII repetitive fragments were about 0.54 kb long, and localized at the distal C-bands of the autosomes and the interstitial C-bands of the X chromosome. Molecular analysis showed two distinct satellite DNA sequences, named the GBH535 and GBH542 families, with high AT contents of about 67 and 66%, respectively. The two repetitive families seem to be derived from a common ancestral sequence, and both families possessed the same 13-bp palindrome sequence. The results of Southern blot hybridization suggest that the sequence of the GBH535 family is conserved in the genomic DNAs of Gryllus species, whereas the GBH542 family is a species-specific sequence.     

玉米8个栽培亚种（类型）的核型和C—带带型的比较研究

本文首次报道了玉米8个亚种、2个亚型和2个杂交品种的核型和Giemsa C-带带型。所有材料的根尖细胞染色体数目均为2n=20。主要由中部和亚中部着丝点染色体组成。第6染色体短臂均具随体,但大小不同。所有材料均显示有亚端带和端带,在第6染色体的短臂上显示有NOR或/和随体带。C-带的分布、总数目和总长度各不相同。其总带数变异于6至18之间,C-带总长度为5.65—11.40％之间。在核型中,具中部着丝点的染色体数目及C-带总数,罕见栽培或原始的类型通常多于广泛栽培的类型。此外,有关核型和C-帝的变异和进化也进行了简略的讨论。     

茅舍血厉螨核型及染色体的C带、G带的研究

本文首次报道了一种革螨——茅舍血厉螨核型及染色体C带、G带的研究。用剖腹取卵法、玻璃纸压片、Giemsa染色,经分析茅舍血厉螨的核型,单倍体n=7,二倍体2n=14。 用氢氧化钡—吉姆萨技术显示茅舍血厉螨染色体C带。在第1、2、4、5染色体上出现恒定的C带部分,第3、6、7染色体上出现不恒定的C带部分。根据C带带型,茅舍血厉螨着丝点的位置可分为近中区域(sm),近端区域(St),末端区域(t)和末端点(T)四类。 G带分析用胰蛋白酶—吉姆萨技术显示。 本文对茅舍血厉螨的核型、革螨染色体研究中螨卵的收集方法和染液的改进、C带带型与着丝粒位置的确定和G带显带问题进行了讨论。     

Equilocality of heterochromatin distribution and heterochromatin heterogeneity in acridid grasshoppers

Comparative fluorescence studies on the chromosome of ten species of acridid grasshoppers, with varying amounts and locations of C-band positive heterochromatin, indicate that the only regions to fluoresce differentially are those that C-band. Within a given species there is a marked tendency for groups of chromosomes to accumulate heterochromatin with similar fluorescence behaviour at similar sites. This applies to all three major categories of heterochromatin — centric, interstitial and telomeric. Different sites within the same complement, however, tend to have different fluorescence properties. In particular, centric C-bands within a given species are regularly distinguishable in their behaviour from telomeric C-bands. Different species, on the other hand, may show distinct forms of differential fluorescence at equilocal sites. These varying patterns of heterochromatin heterogeneity, both within and between species, indicate that whatever determines the differential response to fluorochromes has tended to operate both on an equilocal basis and in a concerted fashion. This is reinforced by the fact that structural rearrangements that lead to the relocation of centric C-bands, either within or between species, may also be accompanied by a change in fluorescence behaviour.We dedicate this paper, with affection, to Professor Hans Bauer on the occasion of his 80th birthday, and in appreciation of his singular contribution to the study of chromosomes     

甘肃紫斑牡丹品种与中原牡丹品种银带和Giemsa C带的研究

分别对甘肃紫斑牡丹品种和中原牡丹品种进行了核型,Ａｇｇｋｐｈｔ Ｇｉｅｎｓａ Ｃ带的研究。发现紫斑牡丹品种核型组成为２ ＝１０＝８ｍ＋２ｓｔ;中原牡丹品种核型组成为２ｎ＝１０＝６ｍ＋２ｓｍ＋２ｓｔ。ＧｉｅｍｓａＣ带带型显示,供试品种均能显示染色体端带,但天染色体端带的数目及分布位置上具品种特异性。     

Cytogenetic study of Callicebus hoffmannsii (Cebidae, Primates) and comparison with C. m. moloch.

Callicebus is a neotropical primate genus divided into four or five groups of species. Species of the moloch group are distributed in the tropical forests of the Amazon basin. The karyotype of Callicebus hoffmannsii (moloch group) was studied by means of G- and C-banding, Ag-NOR staining and in situ hybridization of telomeric probes. C. hoffmannsii had 2n = 50 chromosomes, with ten biarmed and fourteen acrocentric autosomal pairs. The X chromosome was submetacentric and the Y chromosome was a minor acrocentric. Constitutive heterochromatin was detected in the centromeric regions of all chromosomes; in pairs 7 and 10, it was found in the distal regions of the short arms, and distally in the long arm of the X chromosome. Size heteromorphism in C-bands was detected in pairs 7 and 10. Ag-NOR staining revealed a maximum of three nucleolar organizers. Telomeric probes hybridized only at the terminal regions of all chromosomes. Additionally, a comparison was carried out between C. hoffmannsii and C. m. moloch (2n = 48), as previously reported. Both species shared gross chromosomal similarities diverging by a single rearrangement of centric fusion/fission. A high similarity between C. hoffmannsii and C. donacophilus indicated a close association between the moloch and donacophilus groups.     

Banded chromosomes of the owl monkey, Aotus trivirgatus.

Chromosomes of the owl monkey, Aotus trivirgatus, with 2n=54, 53, or 52, have been stained to show quinacrine (Q-) and Giemsa (G-) bands, and a karyotypic arrangement has been proposed based on lengths, centrometric index, and banding pattern. C-bands were present at the centromeric region of every chromosome and over the entire short arm of certain acrocentric chromosomes; 5-methylcytosine was concentrated in the same regions. Bright Q-bands at the telomeric ends of the short arms of some chromosomes probably represent a second type of repetitive DNA. Ag-staining showed that only the chromosomes bearing a secondary constriction are nucleolus organizer chromosomes.     

A simple method to sequentially reveal Q- and C-bands on the same metaphase chromosomes

The Q-C staining procedure, i.e., to treat QM stained preparations with a modified ASG method, conveniently provides Q? and C? (instead of the expected G?) bands on the same metaphase chromosomes. This procedure is especially useful for karyological study of heteroploid cells and interspecific cell hybrids in which extensive chromosomal rearrangements and complex karyotypic compositions are present. A few examples of karyological interest are reported. C-bands, which are either Q+ or Q?, can be divided into two to three subsegments in human chromosomes 1, 9, and 16. These subsegments are connected by a Q?/C?element. Interstitial C-bands could have originated mostly from a C-band without the kinetochore or with the“non-functional” kinetochore.“Double Minutes” are of two kinds, Q+/C+ and Q?/C+. Mechanism for the production of C-bands by the Q-C procedure is briefly discussed.     

The effects of chromatin diminution on the pattern of C-banding in the chromosomes of Acanthocyclops vernalis Fischer (Copepoda: Crustacea)

Chromatin diminution is the loss of selected regions of pre-somatic cell chromosomes during early development, resulting in the removal of a large amount of the genomic DNA from the pre-somatic cells. In copepods, diminution is characterized by the formation of heterochromatically staining regions, or H-segments, which contain the chromatin to be lost. The removal of H-segments during diminution also must represent a major restructuring of the chromosomes which contained them. In order to examine the effects of diminution on the morphology and structure of the chromosomes, the C-banding technique was used. This procedure revealed that most C-bands present in the pre-diminution complement were absent in the post-diminution set. Additionally, in order to explore further the possible composition of the DNA contained in H-segments, a comparison, based on the relationship of C-bands to highly-repetitive DNA in chromosomes, was made between pre-diminution C-bands and H-segments. This comparison showed that not all H-segments are at chromosomal locations which produce a C-band, indicating that H-segments are perhaps not entirely composed of genetically inert DNA, as is currently supposed.     

Bkm sequences are polymorphic in humans and are clustered in pericentric regions of various acrocentric chromosomes including the Y

Summary Probes of uncloned Bkm satellite DNA and a Drosophila clone 2(8), consisting mainly of GATA repeasts related to a major sequence component in Bkm, have been used to probe Southern blots of human male and female DNAs obtained from a Caucasian and an Australian aboriginal population and to human chromosomes in situ. Hybridization was observed to a distinct and an indistint series of bands against a smeared background. The same distinct bands are identified in the DNA samples with both probes, but are most readily detected using the uncloned Bkm probe. Most restriction bands are common to both populations and some are polymorphic. However, certain bands appear to be characteristic of the Australian aboriginal samples. There are no distinct sex-linked patterns. However all of the small acrocentric human chromosomes, including the Y chromosome show hybridization to uncloned Bkm in situ.     

Heterochromatin and interstitial telomeric DNA homology

The purpose of this investigation was twofold. The first objective was to demonstrate that, in most of ten mammalian species commonly used in biomedical research, not all constitutive heterochromatin (C-bands) represents telomeric DNA. For example, the C-bands in human chromosomes, the long arm of the X and the entire Y chromosome of Chinese hamster, and most of the short arms of Peromyscus and Syrian hamster chromosomes are not telomeric DNA. In addition to the usual terminal telomeric DNA in the chromosomes of these mammalian species, the pericentromeric regions of seven or eight Syrian hamster chromosomes and all Chinese hamster chromosomes except pair one have pericentromeric regions that hybridize with telomeric DNA, some in C-bands and some not. The second objective was to describe a simple fluorescence in situ hybridization (FISH) reverse-printing procedure to produce black-and-white microphotographs of metaphase and interphase cells showing locations of telomeric DNA with no loss of resolution. Thus, at least three different types of heterochromatin (telomeric heterochromatin, nontelomeric heterochromatin and a combination of both) are present in these mammalian species, and this simple black-and-white reverse printing of telomeric FISH preparations can depict them economically without sacrificing clarity.     

Distribution of repetitive DNA sequences in chromosomes of five opisthorchid species (Trematoda, Opisthorchiidae)

Genomes of opisthorchid species are characterized by small size, suggesting a reduced amount of repetitive DNA in their genomes. Distribution of repetitive DNA sequences in the chromosomes of five species of the family Opisthorchiidae (Opisthorchis felineus 2n = 14 (Rivolta, 1884), Opisthorchis viverrini 2n = 12 (Poirier, 1886), Metorchis xanthosomus 2n = 14 (Creplin, 1846), Metorchis bilis 2n = 14 (Braun, 1890), Clonorchis sinensis 2n = 14 (Cobbold, 1875)) was studied with C- and AgNOR-banding, generation of microdissected DNA probes from individual chromosomes and fluorescent in situ hybridization on mitotic and meiotic chromosomes. Small-sized C-bands were discovered in pericentric regions of chromosomes. Ag-NOR staining of opisthorchid chromosomes and FISH with ribosomal DNA probe showed that karyotypes of all studied species were characterized by the only nucleolus organizer region in one of small chromosomes. The generation of DNA probes from chromosomes 1 and 2 of O. felineus and M. xanthosomus was performed with chromosome microdissection followed by DOP-PCR. FISH of obtained microdissected DNA probes on chromosomes of these species revealed chromosome specific DNA repeats in pericentric C-bands. It was also shown that microdissected DNA probes generated from chromosomes could be used as the Whole Chromosome Painting Probes without suppression of repetitive DNA hybridization. Chromosome painting using microdissected chromosome specific DNA probes showed the overall repeat distribution in opisthorchid chromosomes.     

Variation in highly repetitive DNA composition of heterochromatin in rye studied by fluorescence in situ hybridization.

The molecular characterization of heterochromatin in six lines of rye has been performed using fluorescence in situ hybridization (FISH). The highly repetitive rye DNA sequences pSc 119.2, pSc74, and pSc34, and the probes pTa71 and pSc794 containing the 25S-5.8S-18S rDNA (NOR) and the 5S rDNA multigene families, respectively, were used. This allowed the individual identification of all seven rye chromosomes and most chromosome arms in all lines. All varieties showed similar but not identical patterns. A standard in situ hybridization map was constructed following the nomenclature system recommended for C-bands. All FISH sites observed appeared to correspond well with C-band locations, but not all C-banding sites coincided with hybridization sites of the repetitive DNA probes used. Quantitative and qualitative differences between different varieties were found for in situ hybridization response at corresponding sites. Variation between plants and even between homologous chromosomes of the same plant was found in open-pollinated lines. In inbred lines, the in situ pattern of the homologues was practically identical and no variation between plants was detected. The observed quantitative and qualitative differences are consistent with a corresponding variation for C-bands detected both within and between cultivars.     

Chromosomal alterations in the karyotype of triticale in comparison with the parental forms

Summary Wheat chromosomes of the primary winter hexaploid and octoploid triticales and of the parental durum and common wheat varieties were studied using morphometric analysis. The size of some heterochromatic segments was shown to change in triticale. Telomeric and intercalary C-bands both increased and decreased in size whereas centromeric bands only increased. The size variability of C-bands in triticale B-genome chromosomes decreased in most of the cases and increased only for several specific C-bands. The C-bands of homologous B-genome chromosomes changed in the same direction in both triticale forms. The changes in size of the C-bands found in R-genome chromosomes detected earlier in these triticale forms (Badaeva et al. 1986) were shown to coincide in their pattern with the size changes of C-bands in homeological B-genome chromosomes. Our data are indicative of regular, directed chromosomal changes in the triticale karyotype.     

Identification of a deletion hotspot on distal mouse chromosome 4 by YAC fingerprinting

Using repetitive elements as probes, genomic DNA fingerprints of four randomly selected yeast artificial chromosome (YAC) clones (two human and two mouse-derived YAC) were analyzed to determine the mutation level following X-ray exposure. Because the repetitive probes were derived from the mammalian host DNA, most of the fingerprint bands originated from the artificial chromosomes and not from the yeast genome. For none of the YAC clones was the mutation frequency elevated following X-ray exposure. However, for one mouse-derived YAC, the mutation level was unusually high (7%; 42 mutants of 607 clones analyzed), whereas for the other three YACs, the mutation level was nearly 0%. Surprisingly, 40 of the 42 mutations were deletions occurring only at three of the 20 mouse specific fingerprint bands. One of the frequently deleted fragments was cloned, sequenced and mapped to distal mouse chromosome 4, which has been repeatedly reported to be the most unstable region of the whole mouse genome, associated with various tumors. Deletion mapping of six YAC mutants revealed this fragment to be completely deleted in four YACs. In the other two mutants, recombination occurred within the fragment, in each case initiated at the same LINE-1 element. In conclusion, the presented YAC fingerprint is a useful tool for detecting and characterizing unstable regions in mammalian genomes.     

Chromosome banding in Amphibia. XXVII. DNA replication banding patterns in three anuran species with greatly differing genome sizes

The mitotic chromosomes of three anuran species, Scaphiopus holbrooki, Litoria infrafrenata and Odontophrynus americanus, were analyzed by means of the 5-bromodeoxyuridine/deoxythymidine (BrdU/dT) replication banding technique. These species exhibit large differences in their genome sizes: S. holbrooki possesses one of the smallest genomes among vertebrates, L. infrafrenata has a genome size near the modal DNA value of most Amphibia, whereas O. americanus is a tetraploid species. BrdU/dT labeling induces reproducible and reliable R- and G-replication bands along the metaphase chromosomes of all three species. Irrespective of the genome size of the species considered, the number of early (R-) and late (G-) replicating bands per haploid karyotype is nearly the same. The chromosomes of the autotetraploid O. americanus can be arranged into sets of four homologous chromosomes (quartets). C-bands and BrdU/dT replication bands reveal heterogeneity within the quartets 1, 3 and 4 that are interpreted as the initiation of a diploidization process.