Action of restriction endonucleases on the DNA and chromosomes of Muntiacus muntjak

Heterochromatin heterogeneity in Hypostomus prope unae (Steindachner, 1878) (Siluriformes, Loricariidae)from Northeastern Brazil

Cytogenetic analyses using C-banding and chromosomal digestion by several restriction enzymes were carried out in four populations (named A, B, C and D) of Hypostomus prope unae (Loricariidae, Hypostominae) from Contas river basin, northeastern Brazil. These populations share 2n=76 and single NORs on the second metacentric pair but exclusive karyotype forms for each locality. Populations A and B presented conspicuous terminal and interstitial heterochromatic blocks on most of acrocentric chromosomes and equivalent to NORs with differences in both position and bearing pair. Population D showed evident marks at interstitial regions and interspersed with nucleolar region while population C presented interstitial and terminal heterochromatin segments, non-coincident with NORs. The banding pattern after digestion with the endonucleases Alu I, Bam HI, Hae III and Dde I revealed a remarkable heterogeneity within heterochromatin, allowing the identification of distinctive clusters of repeated DNA in the studied populations, besides specific patterns along euchromatic regions. The analysis using restriction enzymes has proved to be highly informative, characterizing population differences and peculiarities in the genome organization of Hypostomus prope unae.

Localization of cloned, repetitive DNA sequences in deer species and its implications for maintenance of gene territory

The deer family shows the largest variation in chromosome number known in mammals (2n = 6 to 2n = 70). The drastic rearrangement of the chromosomes allows to test the prediction, based on the chromosome field theory, according to which DNA sequences tend to occupy specific territories within the eukaryotic chromosome. Nuclear DNAs were isolated from eight Deer and two Bovidae species. These DNAs were cleaved with the restriction enzymes Eco RI and Alu I. Following Eco RI digestion highly repetitive sequences formed two bands which were common to all deer species. These bands had about 1520 and 2240 base pairs and were particularly clear in Capreolus capreolus (2n = 70, roe deer). The 1520 band DNA was cloned in plasmid pUC9, nick translated, and hybridized with the DNAs of all ten species. The Capreolus DNA showed a high homology with the DNAs of all the species including the Indian muntjac (Muntiacus muntjak, 2n = 7, male) and the Chinese muntjac (Muntiacus reevesi, 2n = 46). 3H hybridization was carried out in situ with metaphase chromosomes of Cervus elaphus (2n = 68, red deer), M. muntjak, and M. reevesi. In C. elaphus all the chromosomes are heavily labeled except the regions of the arms near the centromere. In the muntjacs all chromosomes and most regions appear to be labeled. These results were checked with a different technique that involved the use of two antibodies and biotin labeling of the DNA. The hybridization picture was essentially the same as obtained with 3H. These results disclose that the 1520 bp DNA piece maintains its main territory independently of the drastic changes in chromosome number.

Human chromosomal bands: nested structure, high-definition map and molecular basis

In this paper, we report investigations on the nested structure, the high-definition mapping, and the molecular basis of the classical Giemsa and Reverse bands in human chromosomes. We found the rules according to which the approximately 3,200 isochores of the human genome are assembled in high (850-band) resolution bands, and the latter in low (400-band) resolution bands, so forming the nested mosaic structure of chromosomes. Moreover, we identified the borders of both sets of chromosomal bands at the DNA sequence level on the basis of our recent map of isochores, which represent the highest-resolution, ultimate bands. Indeed, beyond the 100-kb resolution of the isochore map, the guanine and cytosine (GC) profile of DNA becomes turbulent owing to the contribution of specific sequences such as exons, introns, interspersed repeats, CpG islands, etc. The isochore-based level of definition (100 kb) of chromosomal bands is much higher than the cytogenetic definition level (2-3 Mb). The major conclusions of this work concern the high degree of order found in the structure of chromosomal bands, their mapping at a high definition, and the solution of the long-standing problem of the molecular basis of chromosomal bands, as these could be defined on the basis of compositional DNA properties alone.

Asymmetric staining of Ctenomys chromosomes after treatment with AluI restriction nuclease

After treatment with the endonuclease AluI for 6 or 24 h, chromosomes of two populations of the South American rodent Ctenomys presented an asymmetric banding pattern after Giemsa staining. These asymmetric patterns were chromosome specific (each chromosome of a pair showed different banding pattern) but constant from cell to cell and between homologous chromosomes of the populations analysed. The nature of this peculiar staining is discussed in the light of the interaction between endonucleases and DNA in chromatin of fixed chromosomes.

Localization of chromosome breakpoints induced by AluI and BamHI in Chinese hamster ovary cells treated in the G1 phase of the cell cycle

Intact Chinese hamster ovary cells were exposed to the restriction endonucleases (REs) AluI or BamHI. In metaphase spreads from these cells, 300 breakpoints per RE were localized in G-banded chromosome type aberrations (dicentrics, translocations, rings, terminal and interstitial deletions). The majority of breakpoints induced by both REs were localized in G-light bands and showed a similar distribution of breakpoint clusters. RE digestion of metaphase spreads with AluI induced C-banding, and with BamHI G-banding. The data indicate that nuclease sensitive sites associated with active genes are mainly responsible for the distribution of breakpoints.

Hypomethylation of human heterochromatin detected by restriction enzyme nick translation

Using the restriction enzymes MspI and HpaII in the nick translation procedure it has been shown that decondensation of the paracentric heterochromatin of chromosome 9 during human spermatogenesis is associated with hypomethylation of the DNA sequences in this domain. Somatic cells treated with 5'-azacytidine also showed decondensation of centromeric heterochromatin. In this instance, however, hypomethylation is detected both in the extended heterochromatin at the centromeres and in the euchromatin of the chromosome arms.

Restriction endonuclease digestion patterns of harvest mice (Reithrodontomys) chromosomes: a comparison to G-bands, C-bands, and in situ hybridization

Constitutive heterochromatin of a karyotypically conserved species of harvest mouse was compared to that of three karyotypically derived species of harvest mice by examining banding patterns produced on metaphase patterns produced by two of these restriction endonucleases (EcoRI and MboI) were compared to published G- and C-banded karyotypes and in situ hybridization of a satellite DNA repeat for these taxa. The third restriction endonuclease (PstI) did not produce a detectable pattern of digestion. For the most part, patterns produced by EcoRI and MboI can be related to C-banded chromosomes and in situ hybridization of satellite DNA sequences. Moreover, digestion with EcoRI reveals bands not apparent with these other techniques, suggesting that restriction endonuclease digestion of metaphase chromosomes may provide additional insight into the structure and organization of metaphase chromosomes. The patterns produced by restriction endonuclease digestion are compatible with the chromosomal evolution of these taxa, documenting that in the highly derived taxa not only are the chromosomes rearranged but the abundance of certain sequences is highly variable. However, technical variation and difficulty in producing consistent results even on a single slide with some restriction endonucleases documents the problems associated with this method.

Patterns of digestion of human chromosomes by restriction endonucleases demonstrated by in situ nick translation

A restriction enzyme-nick translation procedure has been developed for localizing sites of restriction endonuclease action on chromosomes. This method involves digestion of fixed chromosome preparations with a restriction enzyme, nick translation with DNA polymerase I in the presence of biotinylated-dUTP, detection of the incorporated biotin label with streptavidinalkaline phosphatase, and finally staining for alkaline phosphatase. Results obtained obtained on human chromosomes using a wide variety of restriction enzymes are described, and compared with results of Giemsa and Feulgen staining after restriction enzyme digestion. Results of nick translation are not in general the opposite of those obtained with Giemsa staining, as might have been expected. Although the nick translation procedure is believed to give a more accurate picture of the distribution of restriction enzyme recognition sites on chromosomes than Giemsa staining, it is clear that the results of the nick translation experiments are affected by accessibility to the enzymes of the chromosomal DNA, as well as by the extractability of the DNA.

Restriction enzymes MspI, HpaII, HaeIII, and HinfI applied to chicken mitotic chromosomes

The restriction enzymes MspI, HpaII, HaeIII, and HinfI were applied in situ to chicken metaphase chromosomes to determine if they denatured specific regions to produce banding patterns. Human metaphase chromosomes were treated simultaneously to serve as controls. The MspI, HpaII, and HaeIII enzymes produced no visible banding patterns in chicken chromosomes. There was slight banding on a few chromosomes in HinfI preparations, which was similar to the occasional spontaneous banding observed in chicken chromosome preparations. The results indicate that these four enzymes do not denature C-band regions in sufficient magnitude to be detected in chicken metaphase chromosomes.

Chromosome markers and karyology of selachians

Among vertebrates, chondrichthyans exhibit peculiar karyotypes and total amount and composition of DNA very different from those of tetrapods and teleosteans. Selachians have relatively large genome sizes (more than 30 pg/N), which are inversely related to the fraction rich in adenine-thymine. Moreover, they show a high chromosome number (2n = 60-100), decreasing in the most specialized species. The karyotypes of Scyliorhinus stellaris, Torpedo ocellata, and T. marmorata have been investigated by several techniques in order to distinguish particular genome fractions along the chromosome arms. C-banding appears to be positive in most telomeric regions in Scyliorhinus and at the interstitial level in the two torpedo species. Studies with restriction enzymes (RE) have just been started in selachians, employing ALU I and HIND III in Scyliorhinus stellaris. The former digests the whole chromosome except the telomeric regions, revealing patterns similar to the C-bands. The latter cuts the chromosomes into several interstitial regions, producing G-bands. Other RE are being studied, which will allow identification in situ of qualitative differences in the various DNAs.

Chromosome banding in Amphibia. XII. Restriction endonuclease banding

Fixed metaphase chromosomes of several species of Amphibia were treated with various restriction endonucleases and subsequently stained with Giemsa. Metaphases of man and chicken were examined in parallel under the same experimental conditions for comparison. The restriction enzymes always induce subsets of the C-banding patterns present in the amphibian karyotypes. The heterochromatic regions can be either resistant or sensitive to the restriction enzyme. The modified C-banding patterns revealed by different restriction endonucleases in the karyotype of the same species can be either extremely dissimilar or almost completely congruent. Correspondingly, the action of the same restriction enzyme on the karyotypes of different species may vary greatly. There is only rarely a correlation between the type of C-banding patterns produced by different restriction endonucleases and their specific base pair recognition sequences. In contrast to mammalian and avian chromosomes, restriction enzymes induce no multiple G-banding patterns in amphibian chromosomes. This is attributed to the difference in organization of the DNA in the genomes of poikilothermic vertebrates. The possible mechanisms of restriction endonuclease banding and the various uses of this technique for amphibian chromosomes are discussed.

Restriction endonuclease resistant chromatin in human chromosomes

The recent addition of restriction endonucleases in obtaining selective bands in the human genome has added a new dimension to molecular genetics. However, a considerable discrepancy exists in banding patterns produced by AluI in chromosomes 19 and 20, by MboI in chromosomes 4, 5, 8, 21 and 22 and by RsaI in chromosomes 12, 21 and 22. The principal causes of these differences are highlighted.

Chromosomal aberrations induced by the restriction endonucleases EcoR I, Pst I, Sal I and Bam HI in CHO cells

4 widely used cohesive end-producing restriction endonucleases (REs), EcoR I, Pst I, Sal I and Bam HI were tested in CHO cells for their aberration-inducing effects. It was demonstrated that all these REs significantly increased the frequencies of aberrant cells, the aberration frequencies per cell and the aberration frequencies per chromosome. The effects of REs on chromosomal aberrations are similar to ionizing radiation, but more minutes and interchange figures are observed. Polyploid cells are more susceptible to RE treatment, an interesting finding which may be explained by the mechanisms leading to the formation of polyploid cells.

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.

Chromosomal aberrations induced in human cultured cells by liposome-encapsulated deoxyribonuclease I

Experiments of incorporation of a nucleolytic enzyme into human cells cultured in vitro have been carried out with the aim of inducing structural chromosome variations. Human heteroploid cells, either as asynchronous populations or enriched in mitoses, and PHA-stimulated lymphocytes were used as recipients. We found that all these cells when exposed to pancreatic DNAase I encapsulated in liposomes, either of multilamellar (MLV) or of small unilamellar (SUV) type, show an incidence of chromosome damage higher than that induced by the enzyme free in the incubation buffer. Our results indicate that liposomes are suitable vehicles for the transfer of an exogenous nuclease into human cultured cells. The enzyme remains functionally active and interacts with nuclear DNA, giving rise to chromosome lesions.

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.

Endonuclease banding of isolated mammalian metaphase chromosomes

Evidence is presented that endonuclease digestion of isolated, unfixed chromosomes results in the production of banding patterns similar to those produced by digestion of fixed, air-dried chromosomes. Mouse L cell chromosomes were isolated under acidic or relatively neutral pH conditions, exposed in situ (as wet mounts on glass slides) or in vitro (in suspension) to micrococcal nuclease, Alu I or Eco RI, treated with a buffered salt solution, and stained with Giemsa. After any of these endonuclease treatments in situ, the centromeric regions of the chromosomes were intensely stained, characteristic of the C-banding observed in fixed chromosomes exposed to the same treatments. Although the fixed chromosomes were morphologically well-preserved after endonuclease digestion, the morphology of chromosomes digested in situ was variable, ranging from normal to swollen to highly distorted chromosomes. In the latter, the endonucleases induced dispersion of non-C-band chromatin; however, C-bands were still apparent as condensed, differentially-stained regions. Exposure of isolated chromosomes to Alu I in vitro also resulted in well-defined C-banding and led to the extraction of about 70% of the chromosomal DNA. From these results, the mechanism of endonuclease-induced C-banding appears to involve the dispersion and extraction of digested chromatin.

DNA cloning and hybridization in deer species supporting the chromosome field theory

The Cervidae show the largest variation in chromosome number found within any mammalian family. The eight species of deer which are the subject of this study vary in chromosome number from 2n = 70 to 2n = 6. Three species of Bovidae are also included since they belong to a closely related family. Digestion of nuclear DNAs with the restriction endonucleases Hae III, Hpa II, Msp I, Eco RI, Xba I, Pst I and Bam HI reveals that there is a series of highly repetitive sequences forming similar band patterns in the different species. There are two bands (1100 and 550 base pairs) which are common to all species although the two families separated more than 40 million years ago. To obtain information on the degree of homology among these conserved sequences we isolated a Bam HI restriction fragment of approximately 770 base pairs from red deer DNA. This sequence was 32P labeled and hybridized by the Southern blot technique with DNAs cleaved with Bam HI, Eco RI, Hpa II and Msp I. Moreover, the same sequence was cloned in the plasmid vector pBR322 nick translated with 32P and hybridized with the DNAs of 8 species of Cervidae and 3 of Bovidae. The same cloned probe was labeled with 3H and hybridized in situ with the metaphase chromosomes of red deer (2n = 68) and Muntiacus muntjak (2n = 7 male). Homologies are still present between the highly repetitive sequences of the 8 species of Cervidae despite the drastic reorganization that led to extreme chromosome numbers. Moreover, the cloned DNA sequence was found to occupy the same position, in the proximal regions of the arms, in both red deer (2n = 68) and M. muntjak (2n = 7 male) chromosomes. The ribosomal RNA genes and the centromeres in these species have also maintained their main territory despite the drastic chromosome reorganization. These results are experimental confirmation of the chromosome field theory which predicted that each DNA sequence has an optimal territory within the centromere-telomere field and tends to occupy this same territory following chromosome reorganization.

Some factors affecting the action of restriction endonucleases on human metaphase chromosomes

We have investigated whether restriction endonucleases produce bands on human chromosomes by extracting DNA, using staining methods which are stoichiometric for DNA. Restriction enzymes that produce C-band patterns appear to remove DNA extensively from chromosome arms. In general, however, those restriction enzymes that produce G-bands do not extract DNA from chromosomes, and their effects are believed to be due to conformational change in the chromosomal DNA; in these cases, the chromosomal regions affected appear to be determined by the chromosome structure and not by the specificity of the enzyme. DNA loss from chromosomes due to digestion by restriction enzymes may in some cases be uniform, although a G-banding pattern is visible after Giemsa staining.

Chromosomal aberrations induced by restriction endonucleases

Restriction endonucleases (REs) are able to induce chromosomal aberrations in Chinese hamster ovary (CHO) cells. The G1 phase of the cell cycle seems to be especially sensitive for the induction of chromosomal aberrations by REs. The different capacities of REs to induce chromosomal aberrations are probably correlated with the number of recognition sites in the genome.

The mechanism and pattern of banding induced by restriction endonucleases in human chromosomes

The mechanism of chromosome banding induced by restriction endonucleases was analyzed by measuring the amount of radioactivity extracted from [14C]thymidine-labeled chromosomes digested first with restriction enzymes and subsequently with proteinase K and DNase I. Restriction enzymes with a high frequency of recognition sites in the DNA produced a large number short DNA fragments, which were extracted from chromosomes during incubation with the enzyme. This loss of DNA resulted in decreased chromosomal staining, which did not occur in regions resistant to restriction enzyme digestion and thus led to banding. Subsequent digestion of chromosomes with proteinase K produced a further loss of DNA, which probably corresponded to long fragments retained in the chromosome by the proteins of fixed chromatin. Restriction enzymes induce chromatin digestion and banding in G1 and metaphase chromosomes, and they induce digestion and the appearance of chromocenters in interphase nuclei. This suggests that the spatial organization and folding of the chromatin fibril plays little or no role in the mechanism of chromosome banding. It was confirmed that the pattern of chromosome banding induced by AluI, MboI, HaeIII, DdeI, RsaI, and HinfI is characteristic for each endonuclease. Moreover, several restriction banding polymorphisms that were not found by conventional C-banding were detected, indicating that there may be a range of variability in the frequency and distribution of restriction sites in homologous chromosome regions.

Mechanism of endonuclease banding of chromosomes

The restriction endonuclease BstNI markedly reduced the extent of Giemsa staining of the C-band regions of methanol/acetic acid-fixed mouse chromosomes air-dried onto glass slides. The enzyme reduced the amount of hybridizable satellite DNA correspondingly, indicating that its effects can be attributed to cutting satellite DNA into fragments short enough to be removed from fixed chromosomes.

Mapping of DNAase I sensitive regions on mitotic chromosomes

We have shown that in fixed mitotic chromosomes from female G. gerbillus cells the inactive X chromosome is distinctly less sensitive to DNAase I than the active X chromosome, as demonstrated by in situ nick translation. These results indicated that the specific chromatin conformation that renders potentially active genes sensitive to DNAase I is maintained in fixed mitotic chromosomes. We increased the sensitivity and accuracy of in situ nick translation using biotinylated dUTP and a specific detection and staining procedure instead of radioactive label and autoradiography and now show that in both human and CHO chromosomes, the DNAase I sensitive and insensitive chromosomal regions form a specific dark and light banding pattern. The DNAase I sensitive dark D-bands usually correspond to the light G-bands, but not all light G-bands are DNAase I sensitive. Identifiable regions of inactive constitutive heterochromatin are in a DNAase I insensitive conformation. Our methodology provides a new and important tool for studying the structural and functional organization of chromosomes.

The action of ultraviolet light on the patterns of banding induced by restriction endonucleases in human chromosomes

The irradiation of metaphase spreads of human cells with ultraviolet (UV) light blocked the chromosome banding induced by Alu I, Mbo I, Dde I, Hinf I, Hae III, and Rsa I restriction endonucleases. At 13 J/m2 there was moderate inhibition of the nuclease action, which was detected as an increase in the stain intensity of chromosomes (Alu I, Mbo I, Dde I, Rsa I) or as a change in the banding pattern (Hinf I, Hae III). AT 70-300 J/m2 the UV-induced blockage was complete; the chromosomes showed no banding, and stain intensity was similar to that of control slides incubated with buffer. BrdU substitution and the irradiation of BrdU-substituted chromosomes with 313 nm light at 1800-15000 J/m2 did not block the action of restriction nucleases. On the other hand, UV irradiation of BrdU-substituted chromosomes inhibited the action of restriction enzymes at the same fluences that blocked the nuclease action in unsubstituted chromosomes. The data indicate that DNA-protein crosslinkage is the factor inhibiting DNA extraction and chromosome banding.

Restriction enzyme banding of mouse metaphase chromosomes

Fixed metaphase chromosomes from mouse strain RIII embryos or A9 cells were treated with a restriction endonuclease, followed by Giemsa staining. Alu I, Hinf I, or Mbo I treatment produced a C-band pattern, and Eco RII or Hae III produced a G-band plus C-band pattern. Ava II and Bst NI each produced a G-band pattern, but on most chromosomes only a small segment of each C-band, adjacent to the centromere, was stained. These tiny residual C-bands may contain a minor satellite located adjacent to the major satellite clusters.

A molecular method for detecting the presence of the human Y chromosome

The presence of the human Y chromosome can be inferred from the detection of a male-specific 3.4-Kb band generated by digestion with the restriction enzyme Hae III. However, direct visualization of this band is sometimes difficult owing to high background of DNA fragments common to both sexes, and Y chromosome length polymorphism. We have shown that the 3.4-Kb band can be detected by filter hybridization to a large DNA fragment (greater than 20 Kb) also generated by Hae III digestion. Since this large DNA fragment is easily isolated from either sex, it should prove useful to determine sex when chromosome analysis is impractical.

Conservation of repetitive DNA sequences in deer species studied by southern blot transfer

The Cervidae show one of the largest variations in chromosome number found within a mammalian family. The five species of the deer family which are the subject of this study vary in chromosome number from 2n = 70 to 2n = 6. Digestion with the restriction enzymes EcoRI, HpaII, HaeIII and MspI reveals that there is a series of highly repetitive sequences forming similar band patterns in the different species. To obtain information on the degree of homology among these conserved sequences we isolated a HpaII restriction fragment of approximately 990 base pairs from reindeer DNA. This DNA sequence was 32P-labelled and hybridized by the Southern blot technique to DNAs cleaved with HpaII and HaeIII from the reindeer and four other Cervidae species. Hybridization to specific restriction fragments was recorded in all species. The patterns of hybridization showed a higher degree of similarity between reindeer, elk and roe deer than between reindeer and the Asiatic species (fallow deer and muntjac). Homologies are still present between the highly repetitive sequences of the five species despite the drastic reorganization that led to a change in chromosome number from 6 to 70.