The effect of restriction enzyme digestion of human metaphase chromosomes on C-band variants of chromosomes 1 and 9

Human metaphase chromosomes, fixed on slides, have beent treated with 8 different restriction endonucleases and 29 combinations of 2 restriction enzymes prior to staining with Giemsa. The endonucleases AluI and DdeI and the combinations AluI + DdeI, AluI + HaeIII, AluI + HinfI, and AluI + MboI have then been used to digest metaphase chromosomes of nine individuals with C-band variants of chromosomes 1 or 9, obtained by the CBG technique. The restriction enzyme resistant chromatin of the paracentromeric regions of chromosomes 1 and 9 has been measured and compared with the corresponding CBG-bands. The size of the enzyme resistant chromatin regions depend upon the type of enzyme(s) used. Treatment with AluI + MboI was the only digestion that acted differently on different chromosome pairs. However, within one pair of homologous chromosomes, all digestions revealed the same variations as conventional C-banding.     

Chromosomal localization of zebrafish AluI repeats by primed in situ (PRINS) labeling.

Two zebrafish AluI repeats were localized in metaphase chromosomes by means of the primed in situ (PRINS) labeling technique, using oligonucleotide primers based on published sequences. An AT-rich, tandemly repeated, long AluI restriction fragment (RFAL1) labeled the (peri)centromeric regions of all chromosomes. The GC-rich short fragment (RFAS) was found to be localized in the paracentromeric regions of 17 chromosome pairs, which were mostly subtelocentric. The RFAS labeling pattern generally fits the previously described chromomycin A3 (CMA3) staining pattern. The differential composition of heterochromatin in zebrafish chromosomes is discussed.     

The differential staining of murine metaphase chromosomes in early embryogenesis after treatment with restrictase AluI in situ]

The picture of differential staining of early mouse embryogenesis metaphasic chromosomes, from the first cleavage up to 10 days of gestation, after digestion by restriction endonuclease AluI was studied. It was shown that depending on the degree of digestion by endonuclease differential bandings of G+C- or C-type were observed. After the least digestion only the first cleavage chromosomes were differently stained. A slight difference in intensity of staining between paternal and maternal chromosomes of the zygote was observed. All the mouse chromosomes were identified after AluI digestion and staining after Giemsa.     

Restriction endonuclease banding of rainbow trout chromosomes

Rainbow trout chromosomes were treated with nine restriction endonucleases, stained with Giemsa, and examined for banding patterns. The enzymes AluI, MboI, HaeIII, HinfI (recognizing four base sequences), and PvuII (recognizing a six base sequence) revealed banding patterns similar to the C-bands produced by treatment with barium hydroxide. The PvuII recognition sequence contains an internal sequence of 4 bp identical to the recognition sequence of AluI. Both enzymes produced centromeric and telomeric banding patterns but the interstitial regions stained less intensely after AluI treatment. After digestion with AluI, silver grains were distributed on chromosomes labeled with [³H]thymidine in a pattern like that seen after AluI-digested chromosomes are stained with Giemsa. Similarly, acridine orange (a dye specific for DNA) stained chromosomes digested with AluI or PvuII in patterns resembling those produced with Giemsa stain. These results support the theory that restriction endonucleases produce bands by cutting the DNA at specific base pairs and the subsequent removal of the fragments results in diminished staining by Giemsa. This technique is simple, reproducible, and in rainbow trout produces a more distinct pattern than that obtained with conventional C-banding methods.     

Some remarks on the use of TaqI to detect highly repetitive DNA sequences in human chromosomes

In the attempt to conclude investigation of the action of restriction endonucleases on eukaryote chromosomes, we carried out a series of experiments digesting in situ human metaphase chromosomes with AluI/TaqI followed by Giemsa staining. We focused on the centromeric regions of chromosomes1, 2 and 16 and noted that those areas appeared as intensely stained blocks after AluI digestion, but were dramatically reduced in size or completely destroyed after subsequent TaqI treatment. These results permitted us to draw some conclusions on the highly repetitive DNA composition of these regions, in terms of alphoid and classical satellite DNAs.     

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.     

The heteromorphic marker on chromosome 18 using restriction endonuclease AluI.

The staining property of pericentromeric heterochromatin of chromosome 18 is compared by C-banding and restriction endonuclease AluI digestion methods. Only a small distal fraction of C-band of chromosome 18 is observed to be resistant to AluI treatment, which positively stained with subsequent Giemsa staining. The resistant fraction is characteristic and usually located toward the short arm. The extensive heterogeneity of constitutive heterochromatin revealed by AluI treatment is useful in demonstrating the heterozygosity of homologous chromosomes. This, in turn, may provide frequent markers to identify the chromosomes 18's. This present approach can be utilized in evaluation of the families to describe the origin of the extra chromosome 18 in Edward syndrome. As an example, one such family has been investigated where the additional chromosome 18 originated due to paternal nondisjunction at meiosis I.     

A new approach in recognition of heterochromatic regions of human chromosomes by means of restriction endonucleases.

The heteromorphisms of C-band regions of human chromosomes are evaluated by means of restriction endonucleases AluI, DdeI, MboI, and RsaI. Every chromosome exhibits heteromorphic markers of the C-band regions except chromosome 8. Each enzyme was found to be highly characteristic in its staining profile, a result that clearly suggests the diversity of heterochromatin. The inherent C-band-region heterochromatin variability that is revealed by these enzymes provides a valuable tool in identifying markers as compared with other previously described techniques.     

Characterization of human chromosomal constitutive heterochromatin

The constitutive heterochromatin of human chromosomes is evaluated by various selective staining techniques, i.e., CBG, G-11, distamycin A plus 4,6-diamidino-2-phenylindole-2-HCl (DA/DAPI), the fluorochrome D287/170, and Giemsa staining following the treatments with restriction endonucleases AluI and HaeIII. It is suggested that the constitutive heterochromatin could be arbitrarily divided into at least seven types depending on the staining profiles expressed by different regions of C-bands. The pericentromeric C-bands of chromosomes 1, 5, 7, 9, 13-18, and 20-22 consist of more than one type of chromatin, of which chromosome 1 presents the highest degree of heterogeneity. Chromosomes 3 and 4 show relatively less consistent heterogeneous fractions in their C-bands. The C-bands of chromosomes 10, 19, and the Y do not have much heterogeneity but have characteristic patterns with other methods using restriction endonucleases. Chromosomes 2, 6, 8, 11, 12, and X have homogeneous bands stained by the CBG technique only. Among the chromosomes with smaller pericentric C-bands, chromosome 18 shows frequent heteromorphic variants for the size and position (inversions) of the AluI resistant fraction of C-band. The analysis of various types of heterochromatin with respect to specific satellite and nonsatellite DNA sequences suggest that the staining profiles are probably related to sequence diversity.     

Electron microscopy and biochemical analysis of mouse metaphase chromosomes after digestion with restriction endonucleases

Electron microscopy (EM) of whole mounted mouse chromosomes, light microscopy (LM), and agarose gel electrophoresis of DNA were used to investigate the cytological effect on chromosomes of digestion with the restriction endonucleases (REs) AluI, HinfI, HaeIII and HpaII. Treatment with AluI produces C-banding as seen by LM, cuts DNA into small fragments, and reduces the density of centromeres and disperses the chromatin of the arms as determined by EM. Treatment with HinfI produces C-banding, cuts DNA into slightly larger fragments than does AluI and increases the density of centromeres and disperses the fibres in the chromosomal arms. Exposure to HaeIII produces G- + C-banding, cuts the DNA into large fragments, and results in greater density of centromeres and reduced density of arms. Finally HpaII digestion produces G-like bands, cuts the DNA into the largest fragments found and results in greater density of centromeres and the best preservation of chromosomal arms detected by EM. These results provide evidence for: (1) REs producing identical effects in the LM (AluI and HinfI) produce different effects in the EM. (2) All enzymes appear to affect C-bands but while REs such as AluI reduce the density of these regions, other enzymes such as HpaII, HaeIII or HinfI increase their density. Conformational changes in the chromatin could explain this phenomenon. (3) The appearance of chromosomes in the EM is related to the action of REs on isolated DNA. The more the DNA is cut by the enzyme, the greater the alteration of the chromosomal ultrastructure.     

An analysis of the action of nonspecific and restriction nucleases on metaphase chromosomes in situ

Patterns of differential staining of Drosophila, mouse, rat, cattle and pig chromosomes were examined after the treatment with nucleases (DNAase I, DNAase II) and restriction enzymes (AluI, HpaII, MspI, BpE, EcoRI). The above effects depend on the species used, on the enzymes and substitution of thymine for bromodeoxyuridine in the chromosomal DNA. It is supposed that such a phenomenon may not only result from the irregular distribution of specific restriction sites along chromosomes but also depend on the specificity of supramolecular organization of the chromosomal DNA.     

The DNA fragments produced by AluI and BstNI digestion of fixed mouse chromosomes

AluI and BstNI restriction endonucleases were used to study cytological and biochemical effects on centromere DNA in fixed mouse chromosomes. These enzymes were employed, as it is known that AluI is incapable of attacking major satellite DNA, contrary to BstNI that is known to cut this DNA fraction into monomers of 234 bp. After digestion in situ, electrophoretic analysis was carried out to characterize the DNA purified (1) from the material remaining on the chromosomes and (2) from the material solubilized from chromosomes. The DNA was then transferred to a nylon filter and ³²P-labelled major satellite DNA was used as a probe for hybridization experiments. Other preparations were simply stained with Giemsa after digestion in situ with AluI and BstNI. Our results show that although restriction endonuclease cleavage primarily depends on DNA base sequence, this factor is not always sufficient to explain nuclease-induced cytological effects. In fact, the structural organization of peculiar regions such as the centromeres of mouse chromosomes might affect cleavage efficiency when restriction enzyme digestion is performed in situ.M.L. Pardue     

The AluI-induced bands in great apes and man: implication for heterochromatin characterization and satellite DNA distribution

Restriction endonucleases have recently been proved to be active on fixed chromatin, producing differences in staining of metaphase chromosomes. In this paper we show the results obtained by treating the metaphase chromosomes of Pan troglodytes, Pan paniscus, and Gorilla gorilla with the restriction enzyme AluI. These results demonstrate qualitative differences in the telomeric heterochromatin between Pan and Gorilla despite the fact that these areas appear homogeneous in the two genera by the C-banding method. The results found with individual chromosomes in the different species also appear relevant, in the light of the evolutionary relationships between these nonhuman primates and man. Lastly, the results suggest the presence, in great apes, of some highly repetitive DNA sequences different from the human satellites I-IV.     

AluI and HaeIII restriction enzyme banding patterns of Macaca fuscata and Cercopithecus aethiops sabaeus chromosomes

AluI and HaeIII restriction endonuclease banding patterns were analyzed in Macaca fuscata and Cercopithecus aethiops sabaeus chromosomes. AluI produced C-negative bands in both species of monkeys, while HaeIII induced the appearance of C-negative bands on Macaca chromosomes and of simultaneous G + C bands on Cercopithecus metaphases.     

In situ digestion of Drosophila virilis polytene chromosomes by AluI and HaeIII restriction endonucleases

Polytene chromosomes of Drosophila virilis were treated with AluI and HaeIII restriction endonucleases. Both enzymes were capable of extensively digesting chromosomal DNA, with the exception of some regions that contain repetitive DNAs. Moreover, a comparison was made between our data and the data already obtained with the same enzymes in D. melanogaster. On this basis, AluI digestion showed that the 5S RNA genes of D. virilis and D. melanogaster have different base composition, while digestion with HaeIII revealed resistance of the histone genes in D. virilis, contrary to what was previously found in D. melanogaster.     

Analysis of the AluI polymorphism in intron 1 of the human coagulation factor VIII gene: a new marker for the hemophilia A carrier detection

Frequencies of the CIT SNP alleles at position 2403 of the human coagulation factor VIII gene intron 1, containing the AluI restriction endonuclease recognition site, were examined. Genomic DNA samples for the analysis were obtained from the consulted women and their relatives from the families with hemophilia A. A total of 221 unrelated X chromosomes were studied. The two allelic variants were found with similar frequencies of T(Alu+), 0.53 and C(Alu-), 0.47. The heterozygosity index evaluated as equal to 0.50 was correlated with the experimental heterozygote number. The absence of a tight linkage between the AluI SNP and the widely used in the hemophilia A gene diagnostics HindIII polymorphism (CIT SNP at position 103 of intron 19) was demonstrated. Summarized informativity of these two markers for obligate carriers and for those detected in this study constituted 68% (32 out of 47). At the same time using one of the markers, only 40% (HindIII) and 51% (AluI) of the consulted women were informative. The new marker was used in 13 prenatal DNA diagnostics of hemophilia A. A new deletion polymorphism (del TGA, position 2281-2283 of intron 1) was described in close proximity of the AluI SNP with the frequency of about 0.05. among the five other SNP of the factor VIII gene examined (Bme 18I, intron 1; HpaII, intron 13; MnlI, exon 14; Bst4CI, exon 25; and MseI, exon 26) no effective diagnostic markers were found. Only the MnlI polymorphism could be recommended for limited usage.     

The karyotype of the Iberian imperial eagle (Aquila adalberti) analyzed by classical and DNA replication banding.

We report here for the first time the karyotype of the Iberian imperial eagle (Aquila adalberti). All eagles examined had a diploid number of 82 chromosomes and a greater number of microchromosomes (12 pairs) than has been found in all other species of the Accipitridae family. This karyotypic evidence corroborates the recent separation of A. adalberti from A. heliaca on the basis of molecular data. RB-FPG banding induced a specific banding pattern that allowed us to identify homologous chromosome pairs and revealed features about late and early replicating regions. Several chromosome banding techniques (C-, CMA3-, and restriction endonuclease banding and silver staining) were used to characterize the karyotype more accurately. Two GC-rich, late-replicating heterochromatin regions were found in the W chromosome. These regions are AluI resistant and can be used for sex determination in this species. All microchromosomes were heterochromatic, GC rich, and late replicating. Silver staining revealed active nucleolus organizing regions on a pair of microchromosomes that were entirely heterochromatic and stained intensely after CMA3-banding. Different chromosome rearrangements are discussed in order to establish the phylogenetic relationship between A. adalberti and its most closely related species, A. heliaca.     

Characterization of constitutive heterochromatin in Cebus apella (Cebidae, Primates) and Pan troglodytes (Hominidae, Primates): comparison to human chromosomes.

Using G bands, some homologies between the chromosomes of Cebus apella (CAP) and human chromosomes are difficult to establish. To solve this problem, we analyzed these homologies by fluorescence in situ hybridization using human whole chromosome probes (ZOO-FISH). The results indicated that 1) the human probe for chromosome 2 partially hybridizes with CAP chromosomes 13 and 5, 2) the human probe for chromosome 3 partially hybridizes with CAP chromosomes 18 and 20, 3) the human probe for chromosome 9 partially hybridizes with CAP chromosome 19, and 4) the human probe for chromosome 14 hybridizes with the p-terminal and q-terminal regions of CAP chromosome 6. However, none of the human probes employed hybridized with the heterochromatic regions of CAP chromosomes. For this reason, we characterized the heterochromatic regions of CAP chromosomes and of the chromosomes of Pan troglodytes (PTR), to allow comparison between CAP, PTR, and human chromosomes using in situ digestion of fixed chromosomes with the restriction enzymes AluI, HaeIII, and RsaI and by fluorescent staining with DA/DAPI. The results show that 1) centromeric heterochromatin is heterogeneous in the three species studied and 2) noncentromeric heterochromatin is homogeneous within each of the three species, but is different for each species. Thus, centromeric heterochromatin undergoes a higher degree of variability than noncentromeric heterochromatin.     

XX:XY sex chromosome system with X heterochromatinization: an early stage of sex chromosome differentiation in the Neotropic electric eel Eigenmannia virescens

An early stage of sex chromosome differentiation is reported to occur in the electric eel Eigenmannia virescens (Pisces, Sternopygidae) from populations of two tributaries of the Paraná river system (Brazil). Cytogenetic studies carried out in the two populations showed that the Mogi-Gua?u population is characterized by 2n = 38 chromosomes and undifferentiated sex chromosomes and the Tietê population presents 2n = 38 both for males and females and an XX:XY sex chromosome system. The X-chromosome is acrocentric, easily recognized by the presence of a conspicuous heterochromatin block in its distal portion; the Y-chromosome is probably one of the medium sized acrocentrics present in the male karyotype. BrdU induced R-bands of the two populations did not reveal any difference in the euchromatic regions of the chromosomes. AluI and HaeIII restriction enzyme digestion patterns and chromomycin A3 staining of the X-chromosome are presented. The possible role of heterochromatinization in the evolution of sex chromosomes in fish is discussed.     

Morphological and biochemical effects of endonucleases on isolated mammalian chromosomes in vitro

Endonuclease digestion of isolated and unfixed mammalian metaphase chromosomes in vitro was examined as a means to study the higher-order regional organization of chromosomes related to banding patterns and the mechanisms of endonuclease-induced banding. Isolated mouse LM cell chromosomes, digested with the restriction enzymes AluI, HaeIII, EcoRI, BstNI, AvaII, or Sau96I, demonstrated reproducible G- and/or C-banding at the cytological level depending on the enzyme and digestion conditions. At the molecular level, specific DNA alterations were induced that correlated with the banding patterns produced. The results indicate that: (1) chromatin extraction is intimately involved in the mechanism of endonuclease induced chromosome banding. (2) The extracted DNA fragments are variable in size, ranging from 200 bp to more than 4 kb in length. (3) For HaeIII, there appears to be variation in the rate of restriction site cleavage in G- and R-bands; HaeIII sites appear to be more rapidly cleaved in R-bands than in G-bands. (4) AluI and HaeIII ultimately produce banding patterns that reflect regional differences in the distribution of restriction sites along the chromosome. (5) BstNI restriction sites in the satellite DNA of constitutive heterochromatin are not cleaved intrachromosomally, probably reflecting an inaccessibility of the BstNI sites to enzyme due to the condensed nature of this chromatin or specific DNA-protein interactions. This implies that some enzymes may induce banding related to regional differences in the accessibility of restriction sites along the chromosome. (6) Several specific nonhistone protein differences were noted in the extracted and residual chromatin following an AluI digestion. Of these, some nonhistones were primarily detected in the extracted chromatin while others were apparently resistant to extraction and located principally in the residual chromatin. (7) The chromatin in constitutive heterochromatin is transiently resistant to cleavage by micrococcal nuclease.