Longitudinal differentiation of metaphase chromosomes of Indian muntjac as studied by restriction enzyme digestion,in situ hybridization with cloned DNA probes and distamycin A plus DAPI fluorescence staining

The longitudinal differentiation of metaphase chromosomes of the Indian muntjac was studied by digestion with restriction enzymes, in situ hybridization with cloned DNA probes and distamycin A plus DAPI (4-6-diamidino-2-phenylindole) fluorescence staining. The centromeric regions of chromosomes 3 and 3 + X of a male Indian muntjac cell line were distinct from each other and different from those of other chromosomes. Digestion with a combination of EcoRI^* and Sau3A revealed a pattern corresponding to that of C-banding. Digestion with AluI, EcoRII or RsaI yielded a band specific to the centromeric region only in chromosomes 3 and 3 + X. Furthermore, HinfI digestion yielded only a band at the centromeric region of chromosome 3, whereas DA-DAPI staining revealed a single band limited to the extreme end of the C-band heterochromatin of the short arm of 3 + X. These results suggest that centromeres of Indian muntjac chromosomes contain at least four different types of repetitive DNA. Such diversity in heterochromatin was also confirmed by in situ hybridization using specific DNA probes isolated and cloned from highly repetitive DNA families. Heterozygosity between chromosome homologs was revealed by restriction enzyme banding. Evidence is presented for the presence of nucleolus organizer regions (NORs) on the long arm of chromosome 1 as well as on the secondary constrictions of 3 and 3 + X.Abbreviations DA distamycin A - DAPI 4-6-diamidino-2-phenylindole - NOR(s) nucleolus organizer region(s) - PBS phosphate-buffered saline - PI propidium iodide     

Localization and characterization of recombinant DNA clones derived from the highly repetitive DNA sequences in the Indian muntjac cells: their presence in the Chinese muntjac

A total of seven, highly repeated, DNA recombinant M13 mp8 clones derived from a Hpa II digest of cultured cells of the Indian muntjac (Muntiacus muntjac vaginalis) were analyzed by restriction enzymes, in situ hybridization, and DNA sequencing. Two of the clones, B1 and B8, contain satellite DNA inserts which are 80% homologous in their DNA sequences. B1 contains 781 nucleotides and consist of tandem repetition of a 31 bp consensus sequence. This consensus sequence, TCCCTGACGCAACTCGAGAGGAATCCTGAGT, has only 3 bp changes, at positions 7, 24, and 27, from the consensus sequence of the 31 bp subrepeats of the bovine 1.715 satellite DNA. The satellite DNA inserts in B1 and B8 hybridize primarily but not specifically to chromosome X, and secondarily to other sites such as the centromeric regions of chromosomes 1 and 2. Under less stringent hybridization conditions, both of them hybridize to the interior of the neck region and all other chromosomes (including chromosomes 3 and Y). The other five DNA clones contain highly repetitive, interdispersed DNA inserts and are distributed throughout the genome except for the neck region of the compound chromosome X+3. Blot hybridization results demonstrate that the satellite DNA component is also present in Chinese muntjac DNA (Muntiacus reevesi) in spite of the very different karyotypes of the Chinese and Indian muntjacs.     

Cloning, characterization and physical mapping of three cervid satellite DNA families in the genome of the Formosan muntjac (Muntiacus reevesi micrurus)

Due to their high sequence diversity even among closely related species, satellite DNA sequences can be a useful molecular marker for phylogenetic and taxonomic analyses. To characterize the satellite DNA in the genome of a native muntjac species of Taiwan, the Formosan muntjac, satellite DNA clones representing three different cervid satellite DNA families from this species were isolated and analyzed. Genomic organization study of these satellite DNAs was also undertaken. Three Formosan muntjac satellite DNA clones were obtained and designated as FM-satI (1,391 bp), FM-satII (1,143 bp) and FM-satIV (1,103 bp), and found to share approximately 82, 81 and 98% sequence homology with the Chinese muntjac satellite I clone (C5), Indian muntjac satellite II clone (Mmv-0.7) and Chinese muntjac satellite IV clone (MR-1.0), respectively. These three satellite DNA families are organized in a pter<--FM-satII-FM-satIV-FM-satI-->qter orientation in the centromeric region with satII closely associated with the telomeric sequences. Satellite DNA sequence comparison, in combination with chromosome data concludes that the Formosan muntjac is likely a subspecies of M. reevesi, closely related to the Chinese muntjac. With the kinetochore satellite II DNA co-localizing with the telomeric sequences, the Formosan muntjac chromosomes could be truly telocentric.     

Karyotypic evolution of a novel cervid satellite DNA family isolated by microdissection from the Indian muntjac Y-chromosome

A minilibrary was constructed from DOP-PCR products using microdissected Y-chromosomes of Indian muntjac as DNA templates. Two microclones designated as IM-Y4-52 and IM-Y5-7 were obtained from negative screening of all three cervid satellite DNAs (satellites I, II, and IV). These two microclones were 295 and 382 bp in size, respectively, and shared 70% sequence homology. Southern blot analysis showed that the IM-Y4-52 clone was repetitive in nature with an 0.32-kb register in HaeIII digest. Sequence comparison revealed no similarities to DNA sequences deposited in the GenBank database, suggesting that the microclone sequences were from a novel satellite DNA family designated as cervid satellite V. A subclone of an Indian muntjac BAC clone which screened positive for IM-Y4-52 had a 3,325-bp insert containing six intact monomers, four deleted monomers, and two partial monomers. The consensus sequence of the monomer was 328 bp in length and shared more than 80% sequence homology with every intact monomer. A zoo blot study using IM-Y4-52 as a probe showed that the strong hybridization with EcoRI digested male genomic DNA of Indian muntjac, Formosan muntjac, Chinese muntjac, sambar deer, and Chinese water deer. Female genomic DNA of Indian muntjac, Chinese water deer, and Formosan muntjac also showed positive hybridization patterns. Satellite V was found to specifically localize to the Y heterochromatin region of the muntjacs, sambar deer, and Chinese water deer and to chromosome 3 of Indian muntjac and the X-chromosome of Chinese water deer.Y.-C. Li and Y.-M. Cheng contributed equally to this work.     

Kinetics of DNA replication in the Indian muntjac chromosomes as studied by quantitative autoradiography

DNA replication patterns of individual chromosomes and their various euchromatic and heterochromatic regions were analyzed by means of quantitative autoradiography. The cultured cells of the skin fibroblast of a male Indian muntjac were pulse labeled with ³H-thymidine and chromosome samples were prepared for the next 32 h at 1–2 h intervals. A typical late replication pattern widely observed in heterochromatin was not found in the muntjac chromosomes. The following points make the DNA replication of the muntjac chromosomes characteristics: (1) Heterochromatin replicated its DNA in a shorter period with a higher rate than euchromatin. (2) Two small euchromatic regions adjacent to centromeric heterochromatin behaved differently from other portions of euchromatin, possessing shorter Ts, higher DNA synthetic rates and starting much later and ending earlier their DNA replication. (3) Segmental replication patterns were observed in the chromosomes 2 and 3 during the entire S phase. (4) Both homologues of the chromosome 3 showed a synchronous DNA replication pattern throughout the S phase except in the distal portion of the long arms during the mid-S phase.     

Cervid satellite DNA and karyotypic evolution of Indian muntjac

Five satellite DNA families (designated as satellite I?CV) have been identified in the Cervidae so far. Among those, satellite I, II and IV are centromere specific. Satellite I and II are shared by large number of deer species, where satellite IV is highly conserved among several deer species examined. Satellite III was initially thought to be roe deer specific but later identified in Chinese water deer as well. SatelliteV is Y-chromosome specific for several Asian deer species examined but also found in the pericentric region of Indian muntjac chromosome 3 and in X chromosome of Chinese water deer. The observation of interstitial hybridization sites on Indian muntjac chromosomes with satellite DNA I probe generated from Chinese muntjac provides the first molecular evidence supporting the tandem fusion theory that 2n=6??/7??of Indian muntjac karyotype could derive from an ancestral Chinese muntjac-like species with 2n=46. Interspecies chromosome painting study and the maximum number of interstitial hybridization detected with satellite I and satellite II DNA probes lend support to the hypothesis that the Indian muntjac karyotype could evolve directly from an ancestral Chinese water deer-like species with 2n=70. Such hypothesis is further substantiated by the finding of satellite V signals presented in specific chromosome regions between the Chinese water deer and the Indian muntjac chromosomes.     

Characterization of extrachromosomal DNA in the flesh fly Sarcophaga bullata

The polytene pupal foot pad cells of the flesh fly Sarcophaga bullata contain numerous extrachromosomal DNA containing granules. We have determined both the origin and the nature of the DNA sequences present in these granules. Studies done with quinacrine staining of seven day old pupal foot-pad polytene nuclei showed that the granules fluoresced very brightly while the chromosomal bands to which the granules were attached did not. The only other highly fluroescent regions of the polytene karyotype were the centromeric heterochromatin of chromosomes C and E and several bands associated with the nucleolus of Chromosome A. When polytene nuclei were hybridized in situ with cRNA made from highly repetitive DNA, many of the granules positively labeled. Most of the label on these slides was concentrated on the centromeric heterochromatin of chromosomes C and E. Quinacrine staining of the foot-pad cells at very early stages of pupal development showed that when granules were present, they were always closely associated with the same two centromeric regions, those of chromosomes C and E. Since the highly repetitive DNA located in these centromeric regions is underreplicated, we conclude that the granules result from an extrusion process which takes place early during the polytenization of these cells. The chromosomal integrity of the centromeric heterochromatin of chromosomes C and E is apparently disrupted and repetitive sequences are dissociated from the chromosomes as DNA granules which then secondarily become associated with chromosomal bands throughout the nucleus.     

Heterochromatin differentiation shows the pathways of karyotypic evolution in Israeli mole rats (Spalax, Spalacidae, Rodentia)

C-banding, base-specific fluorochrome staining (CMA3/DA/DAPI), and comparative genomic hybridization (CGH) were used to analyze the constitutive heterochromatin in two Israeli Spalax species, S. galili (2n = 52) and S. judai (2n = 60). It was shown that C-positive centromeric heterochromatin and some telomeric sites comprise GC-rich DNA sequences in both species. Comparative genomic in situ hybridization revealed slight qualitative differences in highly repetitive sequences in the two Spalax species. Eight acrocentric pairs in S. judai that are involved in Robertsonian rearrangements, possessed composite heterochromatin with a preference of S. judai highly repetitive sequences in the proximal region. Heterochromatin of the sex chromosomes, two biarmed homologous pairs (4 and 5) in both species, and acrocentric chromosomes from the group with a variable centromere position in S. judai was entirely species-specific. The high level of homology in the composition of heterochromatin may relate to the recent divergence of Israeli Spalax. Interspecies heterochromatin differences are discussed in the context of possible mechanisms in the Spalax chromosome evolution.     

CENP-A associated complex satellite DNA in the kinetochore of the Indian muntjac

The centromere/kinetochore complex is a chromosomal assembly that mediates chromosome motility and mitotic regulation by interacting with microtubules of the mitotic spindle apparatus. Centromere protein A (CENP-A) is a histone H3 homolog that is concentrated in the chromatin of the inner kinetochore plate of human chromosomes. To identify DNA sequences associated with the inner kinetochore plate, we used anticentromere autoantibodies to immunoprecipitate CENP-A associated chromatin selectively from Indian muntjac fibroblasts. DNA was cloned from immunoprecipitated CENP-A- associated chromatin and characterized by DNA sequence and hybridization analyses. A novel centromeric satellite DNA sequence was identified and shown by fluorescence in situ hybridization analysis to be present at all centromeres of the Indian muntjac. This satellite DNA constitutes a 972 bp monomer repeat and shows partial homology with satellite II DNA of the white-tailed deer. Southern blot analysis of muntjac genomic DNA suggests that this satellite DNA is present in repetitive tandem arrays and contains complex internal arrangements. In conjunction with previous work showing the association of CENP-A with human α-satellite DNA, we conclude that the mammalian inner kinetochore plate contains a unique form of chromatin that contains CENP-A in association with complex satellite DNA. Received: 18 May 1999; in revised form: 5 July 1999 / Accepted: 20 July 1999     

Characterization of human heterochromatin by in situ hybridization with satellite DNA clones

Biotinylated DNA from two satellite-related, repetitive DNA clones, pHuR 98 and pHuR 195 (specific for chromosomes 9 and 16, respectively), and from a Y-specific clone, pY-3.4A, were hybridized to human metaphase chromosomes using fluoresceinated avidin to detect binding. The chromosomes were simultaneously counterstained with distamycin-DAPI to identify the AT-rich heterochromatin of chromosomes 1, 9, 15, 16, and the Y chromosome. With this method, clear results were obtained under both normal and low stringency conditions, allowing hybridization between molecules sharing 80-85% and 60-65% identity, respectively. Thus, additional sites related to the probes could be identified. A close relationship was shown between the heterochromatin of chromosomes 1 and 16, both hybridizing with clone pHuR 195 under low stringency. Hybridization with clone pHuR 98 was highly specific for chromosome 9, even under low stringency. A relationship between chromosomes 9, 15, and the Y chromosome, however, was shown by hybridization with clone pY-3.4A. The chromosomal distribution of the three repetitive DNA clones used in this study, and data from the literature, are in accordance with the distribution of the heterochromatin types characterized by staining with different fluorescent dyes and dye combinations. Furthermore, our sequence data for clones pHuR 98 and pHuR 195 may explain the fluorescent properties on which the cytogenetic classification of the heterochromatin is based.     

Comparative gene mapping in the species Muntiacus muntjac.

An extreme case of chromosomal evolution is presented by the two muntjac species Muntiacus muntjac (Indian muntjac, 2n = 6 [females], 7 [males]) and M. reevesi (Chinese muntjac, 2n = 46). Despite disparate karyotypes, these phenotypically similar species produce viable hybrid offspring, indicating a high degree of DNA-level conservation and genetic relatedness. As a first step toward development of a comparative gene map, several Indian muntjac homologs of known human type I anchor loci were mapped. Using flow-sorted, chromosome-specific Southern hybridization techniques, homologs of the protein kinase C beta polypeptide (PRKCB1) and the DNA repair genes ERCC2 and XRCC1 have been assigned to Indian muntjac chromosome 2. The male-specific ZFY gene was presumptively mapped to Indian muntjac chromosome Y2. Ultimate generation of a comparative physical map of both Indian and Chinese muntjac chromosomes will prove invaluable in the study of mammalian karyotype evolution.     

Characterization of ancestral chromosome fusion points in the Indian muntjac deer

Tandem fusion, a rare evolutionary chromosome rearrangement, has occurred extensively in muntjac karyotypic evolution, leading to an extreme fusion karyotype of 6/7 (female/male) chromosomes in the Indian muntjac. These fusion chromosomes contain numerous ancestral chromosomal break and fusion points. Here, we designed a composite polymerase chain reaction (PCR) strategy which recovered DNA fragments that contained telomere and muntjac satellite DNA sequence repeats. Nested PCR confirmed the specificity of the products. Two-color fluorescence in situ hybridization (FISH) with the repetitive sequences obtained and T₂AG₃ telomere probes showed co-localization of satellite and telomere sequences in Indian muntjac chromosomes. Adjacent telomere and muntjac satellite sequences were also seen by fiber FISH. These data lend support to the involvement of telomere and GC-rich satellite DNA sequences during muntjac chromosome fusions.Communicated by E.A. NiggAccession numbers: AY322158, AY322159, AY322160     

A combined approach to mapping the proximal border of the right arm of polytene chromosome 2 in Drosophila melanogaster otu 11

A combined approach based on cytological observations in situ hybridization, and qualitative Southern-blot analyses were used to localize the proximal border of the right arm of polytene chromosome 2 in Drosophila melanogaster otu 11 strain. A genetically functional chromosome 2 is bounded by "deletions" C', C, D, B, A and ms2-10. Using in situ hybridization in conjunction with comparative quantitative Southern-blot hybridization to deletions in centromeric heterochromatin, DNA of specific centromeric clone lambda20p1.4 was localized with respect to "deletions" and on otu 11 polytene chromosomes. Comparison of hybridization sites of lambda20p1.4 on polytene chromosomes, and its amount in mutant lines of D. melanogaster carrying known "deletions" in the centromeric heterochromatin enabled us to localize the proximal border of the right arm of chromosome 2 in D. melanogaster otu 11 strain between the 39/40 region and hybridization site of the k20p1.4 DNA fragment.     

5-Azacytidine- and Hoechst-induced aneuploidy in Indian muntjac

Hoechst 33258 (bis-benzimidazole) and 5-azacytidine (5-AC) cause decondensation of the pericentric heterochromatin in mouse and aberrations in the sequence of centromere separation apparently by different mechanisms. We treated the male Indian muntjac cells (2n=7), which do not undergo decondensation of the pericentric heterochromatin, to study if these chemicals would result in induction of aneuploidy limited to the Y(2) chromosome. This paper reports that both agents result in aneuploidy primarily limited to one chromosome, the Y(2). It is likely that other chromosomes are not tolerated in aneuploid condition because every chromosome carries some household genes including those essential for mitotic progression. The loss/gain of the Y(2) chromosome is tolerated because it is the smallest chromosome and is almost entirely composed of constitutive heterochromatin. Since Indian muntjac has only three pairs of large chromosomes comprising its basic genome, which can be clearly viewed under high dry objective, these cells are very suitable for the preliminary analysis of aneuploidy-inducing ability of various chemicals.     

黑麂和费氏麂四种卫星DNA的克隆特征和染色体定位

近年来,分子细胞遗传学研究已基本证实了染色体的串联融合(端粒-着丝粒融合)是麂属动物核型演化的主要重排方式。尽管染色体串联融合的分子机制还不清楚,但通过染色体的非同源重组,着丝粒区域的卫星DNA被认为可能介导了染色体的融合。以前的研究发现在赤麂和小麂染色体的大部分假定的串联融合位点处存在着非随机分布的卫星DNA。然而在麂属的其他物种中,这些卫星DNA的组成以及在基因组中的分布情况尚未被研究。本研究从黑麂和费氏麂基因组中成功地克隆了4种卫星DNA(BMC5、BM700、BM1.1k和FM700),并分析了这些卫星克隆的特征以及在小麂、黑麂、贡山麂和费氏麂染色体上的定位情况。结果表明,卫星I和IIDNA(BMC5,BM700和FM700)的信号除了分布在这些麂属动物染色体的着丝粒区域外,也间隔地分布在这些物种的染色体臂上。其研究结果为黑麂、费氏麂和贡山麂的染色体核型也是从一个2n=70的共同祖先核型通过一系列的串联融合进化而来的假说提供了直接的证据。     

Defining the orientation of the tandem fusions that occurred during the evolution of Indian muntjac chromosomes by BAC mapping

The Indian muntjac (Muntiacus muntjak vaginalis) has a karyotype of 2n=6 in the female and 7 in the male, the karyotypic evolution of which through extensive tandem fusions and several centric fusions has been well-documented by recent molecular cytogenetic studies. In an attempt to define the fusion orientations of conserved chromosomal segments and the molecular mechanisms underlying the tandem fusions, we have constructed a highly redundant (more than six times of whole genome coverage) bacterial artificial chromosome (BAC) library of Indian muntjac. The BAC library contains 124,800 clones with no chromosome bias and has an average insert DNA size of 120 kb. A total of 223 clones have been mapped by fluorescent in situ hybridization onto the chromosomes of both Indian muntjac and Chinese muntjac and a high-resolution comparative map has been established. Our mapping results demonstrate that all tandem fusions that occurred during the evolution of Indian muntjac karyotype from the acrocentric 2n=70 hypothetical ancestral karyotype are centromere–telomere (head–tail) fusions.     

Novel sequencing strategy for repetitive DNA in a Drosophila BAC clone reveals that the centromeric region of the Y chromosome evolved from a telomere

The centromeric and telomeric heterochromatin of eukaryotic chromosomes is mainly composed of middle-repetitive elements, such as transposable elements and tandemly repeated DNA sequences. Because of this repetitive nature, Whole Genome Shotgun Projects have failed in sequencing these regions. We describe a novel kind of transposon-based approach for sequencing highly repetitive DNA sequences in BAC clones. The key to this strategy relies on physical mapping the precise position of the transposon insertion, which enables the correct assembly of the repeated DNA. We have applied this strategy to a clone from the centromeric region of the Y chromosome of Drosophila melanogaster. The analysis of the complete sequence of this clone has allowed us to prove that this centromeric region evolved from a telomere, possibly after a pericentric inversion of an ancestral telocentric chromosome. Our results confirm that the use of transposon-mediated sequencing, including positional mapping information, improves current finishing strategies. The strategy we describe could be a universal approach to resolving the heterochromatic regions of eukaryotic genomes.     

Isolation and chromosomal localization of a germ line-specific highly repetitive DNA family in Acricotopus lucidus (Diptera, Chironomidae)

. In the chironomid Acricotopus lucidus, parts of the genome, the germ line-limited chromosomes, are eliminated from the future soma cells during early cleavage divisions. A highly repetitive, germ line-specific DNA sequence family was isolated, cloned and sequenced. The monomers of the tandemly repeated sequences range in size from 175 to 184 bp. Analysis of sequence variation allowed the further classification of the germ line-restricted repetitive DNA into two related subfamilies, A and B. Fluorescence in situ hybridization to gonial metaphases demonstrated that the sequence family is highly specific for the paracentromeric heterochromatin of the germ line-limited chromosomes. Restriction analysis of genomic soma DNA of A. lucidus revealed another tandem repetitive DNA sequence family with monomers of about 175 bp in length. These DNA elements are found only in the centromeric regions of all soma chromosomes and one exceptional germ line-limited chromosome by in situ hybridization to polytene soma chromosomes and gonial metaphase chromosomes. The sequences described here may be involved in recognition, distinction and behavior of soma and germ line-limited chromosomes during the complex chromosome cycle in A. lucidus and may be useful for the genetic and cytological analysis of the processes of elimination of the germ line-limited chromosomes in the soma and germ line. Received: 12 April 1997; in revised form 26 June 1997 / Accepted: 29 June 1997     

Constitutive heterochromatin polymorphisms in human chromosomes identified by whole comparative genomic hybridization

Whole comparative genomic hybridization (W-CGH) is a new technique that reveals cryptic differences in highly repetitive DNA sequences, when different genomes are compared using metaphase or interphase chromosomes. W-CGH provides a quick approach to identify differential expansion of these DNA sequences at the single-chromosome level in the whole genome. In this study, we have determined the frequency of constitutive chromatin polymorphisms in the centromeric regions of human chromosomes using a whole-genome in situ cross-hybridization method to compare the whole genome of five different unrelated individuals. Results showed that the pericentromeric constitutive heterochromatin of chromosome 6 exhibited a high incidence of polymorphisms in repetitive DNA families located in pericentromeric regions. The constitutive heterochromatin of chromosomes 5 and 9 was also identified as highly polymorphic. Although further studies are necessary to corroborate and assess the overall incidence of these polymorphisms in human populations, the use of W-CGH could be pertinent and of clinical relevance to assess rapidly, from a chromosomal viewpoint, genome similarities and differences in closely related genomes such as those of relatives, or in more specific situations such as bone marrow transplantation where chimerism is produced in the recipient.     

Identification of an Indian muntjac DNA fragment preferentially hybridizing to the X-chromosome

Upon digestion of DNA from male and female Indian muntjac (Muntiacus muntjak) fibroblasts with the restriction enzyme Hae III or Alu I, a prominent fragment of DNA (greater than 20 kb in length) was observed. This excluded DNA (ex-DNA) appeared not to contain sequences recognized by a variety of restriction enzymes and constituted about 0.6% of the total DNA in the female genome. For equal amounts of DNA digested, female DNA contained more of this material. In situ hybridization indeed revealed strong hybridization of the ex-DNA to the entire X chromosome with a few less intense sites of hybridization on other chromosomes. Hybridization studies against total muntjac DNA indicated the presence of repetitive sequences in the ex-DNA. These repetitive sequences did not cross-hybridize with human or mouse DNA.