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 of 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.     

DNA-protein interactions and chromosome banding

Pancreatic DNase I was used as a probe to study DNA-protein interactions in condensed and extended chromatin fractions isolated from Chinese hamster liver, and in human lymphocyte and mouse L cell metaphase chromosomes in situ. By studying the rate of digestion of chromatin DNA by DNase, we have previously shown that DNA in extended chromatin is more sensitive to DNase digestion than that in condensed chromatin. In the current investigation, we have examined whether this differential sensitivity of the chromatin fractions to DNase is due to differences in protein binding to DNA or differences in the degree of chromatin condensation. By “decondensing” the condensed chromatin and comparing its rate of digestion to that of untreated condensed and extended chromatin, it was found that differences in the degree of binding of proteins to DNA rather than the degree of condensation of the chromatin primarily determines the sensitivity of each fraction to DNase. Extraction of the various classes of chromosomal proteins, followed by DNase digestion of the residual chromatin revealed that both the histone and non-histone proteins protect the DNA in the chromatin fractions from DNase attack; however, the more tightly associated non-histones appear to be specifically responsible for the differential sensitivity of the chromatin fractions to DNase digestion. These non-histones may be more tightly associated with the DNA in condensed than in extended chromatin, thereby protecting the DNA in condensed chromatin against DNase attack to a greater extent than that in extended chromatin. When metaphase chromosomes were briefly digested with DNase in situ and subsequently stained with Feulgen reagent, incontrovertible C-banding and some G-banding was obtained. This DNaseinduced banding demonstrates that the DNA in C-band and possibly G-band regions is less accessible to DNase than that in the interband regions, and our biochemical data suggest that this differential accessibility is caused by differential DNA-protein binding such that the non-histones are more tightly coupled to the DNA in the G- and C-band regions than they are in the interbands. Differences in the binding of non-histones to DNA in different segments of the metaphase chromosome may be involved in the mechanism of G- and C-banding.     

Karyotypic characterization of Iheringichthys labrosus (Pisces, Pimelodidae): C-, G- and restriction endonuclease banding

Various chromosomal banding techniques were utilized on the catfish, Iheringichthys labrosus, taken from the Capivara Reservoir. C-banding regions were evidenced in telomeric regions of most of the chromosomes. The B microchromosome appeared totally heterochromatic. The restriction endonuclease AluI produced a banding pattern similar to C-banding in some chromosomes; the B microchromosome, when present, was not digested by this enzyme and remained stained. G-banding was conspicuous in almost all the chromosomes, with the centromeres showing negative G-banding. When the restriction endonuclease BamHI was used, most of the telomeres remained intact, while some centromeres were weakly digested. The B chromosome was also not digested by this enzyme. The first pair of chromosomes showed a pattern of longitudinal bands, both with G-banding and BamHI; this was more evident with G-banding. This banding pattern can be considered a chromosomal marker for this population of I. labrosus.     

In situ nick translation of human chromosomes using Alu I: unmasking of recognition sites by proteinase K pretreatment

Human chromosomes prepared according to routine methods were treated with the restriction endonuclease Alu I followed by staining with Giemsa solution or fluorescent dyes. This procedure results in a C-band-like appearance of the chromosomes due to removal of DNA from euchromatic chromosomal regions. The resistance of heterochromatic regions against cleavage by the enzyme has mainly been interpreted by the absence or rareness of recognition sites for this particular enzyme in these regions. Proteinase K pretreatment followed by a nick translation procedure with Alu I was combined to check this hypothesis. The results show that heterochromatic chromosomal regions can also be labelled. Thus, they are not characterized by a lack of recognition sites. Gradual deproteinisation of chromosomes changes the labelling pattern from a reverse C-banding pattern to a C-band-like appearance. The resistance of heterochromatic chromosomal parts revealed by the technique is mainly due to local chromatin configuration rather than to the underlying DNA sequence itself.     

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.     

Cytological and electrophoretic analysis of DNA methylation in the holocentric chromosomes of Megoura viciae (Homoptera, Aphididae).

Chromosomal and purified DNA methylation patterns were determined in the holocentric chromosomes of Megoura viciae by treatment with MspI and HpaII. Both enzymes produced a clear C-like banding pattern but widely digested one telomere of the X chromosome, which appeared as heterochromatic after C-banding treatment and brightly fluorescent after chromomycin A3 staining. Quantitative microfluorometric evaluations of DNA extraction performed on cytological preparations showed that both isoschizomers resulted in the same DNA extraction (about 30%). Contrary to what was found by in situ endonuclease treatment, the electrophoretic patterns of purified and digested DNA showed that digestion with MspI was slightly more extensive than that with HpaII in a zone of fragments ranging from 23 to 9 kb. This result indicates that aphid chromatin is not wholly unmethylated. The discrepancy between electrophoretic and cytological data has been explained by taking into consideration that DNA fragments with high molecular weights could be cleaved in situ by the enzymes but not extracted from the chromatin.     

Satellite III DNA: Regions of extreme endonuclease resistance and interindividual polymorphism in the Mb size range

Southern analysis of within-gel digested and restricted human cells has revealed very large Satellite III restriction fragments which show clear inter-individual length polymorphism. The Mb and sub-Mb length of these fragments indicate that they arise from regions of heterochromatin which contain homogeneous Satellite III sequences of peculiar resistance to common endonucleases. Based on sequence alone, such regions would be little digested by endonuclease digestion of chromatin in metaphase, regardless of its method of preparation. Polymorphic regions such as these might be expected to stain as part of the C-banding seen in endonuclease treated metaphase chromosomes, and may in part account for inter-individual C-band heteromorphisms.     

A sequence of the yeast 2 micron DNA plasmid chromosome near the origin of replication is exposed to restriction endonuclease digestion

The yeast 2 μm DNA plasmid nucleoprotein complex was subjected to restriction endonuclease digestion to ascertain whether all possible sites are equally accessible to hydrolysis. When plasmid nucleoprotein complexes which had been fixed with formaldehyde were exhaustively digested with restriction endonucleases HinfI or CfoI, only a few of the limit digest products were produced. Furthermore, the limited set of restriction endonuclease sites exposed in formaldehyde-treated plasmid chromosomes could be shown to be preferentially hydrolyzed when plasmid chromosomes which had not been treated with formaldehyde were digested with the same restriction endonucleases. Mapping of the preferred sites revealed that they mapped to the region of the plasmid near the replication origin. These results demonstrate that the protection of DNA from nuclease activity is not constant along the plasmid chromatin, and that a region near the replication origin is preferentially exposed to endonuclease hydrolysis.     

Structure of eukaryotic chromatin. Evaluation of periodicity using endogenous and exogenous nucleases.

DNA isolated from (a) liver chromatin digested in situ with endogenous Ca2+, Mg2+-dependent endonuclease, (b) prostate chromatin digested in situ with micrococcal nuclease or pancreatic DNAase I, and (c) isolated liver chromatin digested with micrococcal nuclease or pancreatic DNAase I has been analyzed electrophoretically on polyacrylamide gels. The electrophoretic patterns of DNA prepared from chromatin digested in situ with either endogenous endonuclease (liver nuclei) or micrococcal nuclease (prostate nuclei) are virtually identical. Each pattern consists of a series of discrete bands representing multiples of the smallest fragment of DNA 200 +/- 20 base pairs in length. The smallest DNA fragment (monomer) accumulates during prolonged digestion of chromatin in situ until it accounts for nearly all of the DNA on the gel; approx. 20% of the DNA of chromatin is rendered acid soluble during this period. Digestion of liver chromatin in situ in the presence of micrococcal nuclease results initially in the reduction of the size of the monomer from 200 to 170 base pairs of DNA and subsequently results in its conversion to as many as eight smaller fragments. The electrophoretic pattern obtained with DNA prepared from micrococcal nuclease digests of isolated liver chromatin is similar, but not identical, to that obtained with liver chromatin in situ. These preparations are more heterogeneous and contain DNA fragments smaller than 200 base pairs in length. These results suggest that not all of the chromatin isolated from liver nuclei retains its native structure. In contrast to endogenous endonuclease and micrococcal nuclease digests of chromatin, pancreatic DNAase I digests of isolated chromatin and of chromatin in situ consist of an extremely heterogeneous population of DNA fragments which migrates as a continuum on gels. A similar electrophoretic pattern is obtained with purified DNA digested by micrococcal nuclease. The presence of spermine (0.15 mM) and spermidine (0.5 mM) in preparative and incubation buffers decreases the rate of digestion of chromatin by endogenous endonuclease in situ approx. 10-fold, without affecting the size of the resulting DNA fragments. The rates of production of the smallest DNA fragments, monomer, dimer, and trimer, are nearly identical when high molecular weight DNA is present in excess, indicating that all of the chromatin multimers are equally susceptible to endogenous endonuclease. These observations points out the effects of various experimental conditions on the digestion of chromatin by nucleases.     

DNase I digestion as a tool for the quantitative evaluation of C-heterochromatic-DNA in situ.

The amount of DNA resisting the C-banding pre-treatments (C-heterochromatic-DNA) was found to account for the interspecific differences of genome size in different Primate groups. The evaluation of this parameter is therefore of great interest in cytotaxonomy. In this work, DNase I digestion was used instead of the pre-treatments C-banding, in an attempt to set up a suitable method for the quantitative evaluation of C-heterochromatic-DNA in both metaphase chromosomes and interphase chromatin. In fact DNase I is known to preferentially digest "active or potentially active" chromatin, and the highly repetitive and inactive DNA in C-heterochromatin should characteristically resist DNase I cleavage. As a model system, differently fixed mouse splenocytes were treated with DNase I for various times, and the digestion was monitored by flow cytometry after propidium iodide staining. In addition, mouse metaphase preparations from lymphocyte cultures were also digested with DNase I, and the amount of residual DNA was evaluated by static microfluorometry. Under controlled conditions of fixation, enzyme concentration, time and temperature, the same limit-digest can be obtained in both interphase nuclei and metaphases, which corresponds to the amount of residual DNA after C-banding and has a C-banding-like pattern in chromosomes.     

The selective digestion of polytene and mitotic chromosomes of Drosophila melanogaster by the Alu I and Hae III restriction endonucleases

Polytene and mitotic chromosomes of Drosophila melanogaster were treated with either Alu I or Hae III restriction endonucleases. Subsequent staining with the DNA-specific fluorochrome ethidium bromide showed that these enzymes are capable of selectively digesting chromosomal DNA in fixed cytological preparations, as previously shown in mammalian metaphase chromosomes. Alu I or Hae III digestion made possible the localization in situ of some highly repetitive DNAs in both polytene and mitotic chromosomes, while only Alu I permitted the localization of the 5S RNA genes on the polytene chromosomes of D. melanogaster.     

The ultrastructure of G- and C-banded chromosomes

A method of visualizing chromosome bands by electron microscopy has been used to investigate the fine structural organization of G- and C-banded chromosomes. The following information has been obtained:

1. 1. G-bands, produced by trypsinization, were electron dense regions of highly packed chromatin fibres separated by regions in which the chromatin fibres were much less densely packed (interbands).

2. 2. Several degrees of chromatin dispersion were apparent in trypsinized chromosomes. Such dispersion was not a prerequisite for the initial visualization of G-bands, however the progressive pattern of dispersion indicated that the bands were relatively more resistant to dispersion than the interbands.

3. 3. After fixation and trypsinization, individual chromatin fibres measured 250 Å in diameter and appeared morphologically similar to control chromatin fibres seen by whole mount electron microscopy.

4. 4. In trypsinized chromosome complements, the chromosomes often appeared to be interconnected to one another by chromatin fibres. The evidence indicates that these interchromosomal fibres are artefacts produced by the overlapping of dispersed chromatin fibres.

5. 5. When the same metaphase chromosome was observed by both light and electron microscopy, some of the light microscopic G-bands were represented by two or more ultrastructural bands. The number of bands seen in metaphase chromosomes by electron microscopy appears to approach the increased number of bands generally seen in prometaphase chromosomes by light microscopy.

6. 6. C-banding methods (NaOH treatment or overtrypsinization) resulted in the extraction of variable amounts of chromatin from the non C-band regions of the chromosomes, however the constitutive heterochromatin remained highly condensed and resistant to extraction. This result supports the hypothesis that the mechanism of C-banding involves the selective loss of non C-band chromatin.

     

Banding Human Chromosomes Using a Combined C-Banding-Fluorochrome Staining Technique

Slides pretreated for C-banding and stained with DAPI or CMA3 show different banding patterns in human metaphase chromosomes compared to those obtained with either standard Giemsa C-banding or fluorochrome staining alone. Human chromosomes show C-plus DA-DAPI banding after C-banding plus DAPI and enhanced R-banding after C-banding plus Chromomycin A3 staining. If C-banding preferentially removes certain classes of DNA and proteins from different chromosome domains, C-banding pre-treatment may cause a differential DNA extraction from G- and R-bands in human chromosomes, resulting in a preferential extraction of DNA included in G-bands. This hypothesis is partially supported by the selective cleavage and removal of DNA from R-bands of restriction endonuclease HaeIII with C-banding combined with DAPI or Chromomycin A3 staining. Structural factors relating to regional differences in DNA and/or proteins could also explain these results.     

Counterstained enhancement of TaqI resistant sites after distamycin A/diamidinophenylindole treatment

Numerous selective and differential staining techniques have been used to investigate the hierarchical organisation of the human genome. This investigation demonstrates the unique characteristics that are produced on fixed human chromosomes when sequential procedures involving restriction endonuclease TaqI, distamycin A (DA) and 4,6-diamidino-2-phenylindole (DAPI) are employed. TaqI produces extensive gaps in the heterochromatic regions associated with satellite II and III DNAs of human chromosomes 1, 9, 15, 16 and Y. DA/DAPI selectively highlights, as brightly fluorescent C-bands, the heterochromatin associated with the alpha, beta, satellite II and III DNAs of these chromosomes. When DA and DAPI are used on chromosomes before TaqI digestion, and then stained with Giemsa, the centromeric regions appear to be more resistant, producing a distinct C-banding pattern and gaps in the heterochromatin regions. Sequential use of the DA/DAPI technique after TaqI treatment produces a bright fluorescence on the remaining pericentromeric regions of chromosomes 1, 9, 16 and Y, which also displayed a cytochemically unique banding pattern. This approach has produced specific enhanced chromosomal bands, which may serve as tools to characterize genomic heterochromatin at a fundamental level.     

Alterations induced in mouse chromosomes by restriction endonucleases

Fixed chromosomes of mouse have been treated with Alu I, Eco RII, Hind III or Bam HI restriction endonucleases and subsequently stained with either Giemsa, Ethidium Bromide or Acridine Orange. The results obtained have been discussed in the light of preferential or non-preferential extraction of DNA from specific chromosome areas following enzyme digestion. The possible involvement of a particular structural organization of some classes of heterochromatin has been hypothesized to account for the findings after Alu I or Eco RII treatment. The meaning of the Giemsa banding observed after Hind III or Bam HI digestion has also been considered, in comparison to the different stain responses obtained by using a DNA-specific dye such as Ethidium Bromide.     

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 Alu I-induced bands in metaphase chromosomes of orangutan (Pongo pygmaeus)

Summary Restriction endonucleases have been recently proved to be active on fixed chromosomes, thus they are useful in chromatin structure studies. Within this class of enzymes, Alu I is able to detect the presence and localization of highly repetitive DNA sequences in human and in other mammalian and dipteran species. In this paper the pattern obtained on fixed metaphase chromosomes of orangutan (Pongo pygmaeus) by Alu I digestion and Giemsa staining is shown. The results are discussed in the light of the distribution, in this species, of the I–IV human satellite DNAs. It is also suggested that in Pongo some highly repetitive sequences, different from the major human satellites, are present.     

Characterization of chromosome replication during S-phase with bromodeoxyuridine labelling in Chinese hamster ovary and HeLa cells

The same C-banded human polymorphic chromosomes were observed in the light microscope (LM) and then in the scanning electron microscope (SEM) to investigate the structural changes produced by the C-banding technique. C-banded regions, which stained positively in LM, were highly condensed with tightly packed chromatin fibres, resembling non-banded chromosomes. In striking contrast, adjacent non-C-banded regions were represented by loosely arranged fibres, resembling G-banded chromosomes. The significance of these observations in relation to current theories on the effects of C-banding on chromosome structure is discussed.     

Selective digestion of mouse chromosomes with restriction endonucleases. I. Scaffold-like structures and bands by electron microscopy

Mouse chromosomes from the L929 cell line have been digested with the restriction endonuclease HaeIII and analyzed by electron microscopy. Results show a different effect of the enzyme depending on the conditions of the digestion. Thus, while chromosomes digested in suspended cells show a double scaffold-like structure per chromatid, a similar banding to that found in chromosomes treated for light microscopy is obtained when chromosomes are digested on grids. Some aspects concerning the capacity of the cleaved DNA to be removed from the chromatin are discussed.     

Hinf I restriction endonuclease digestion on human fixed metaphase chromosomes

The authors report on the activity of Hinf I restriction endonuclease on human fixed metaphase chromosomes. Experiments performed by digesting chromosomes just after harvesting or after ageing in methanol-acetic acid displayed a different pattern of digestion on metaphases, since only aged preparations showed gaps on heterochromatic regions of chromosomes 1, 9 and 16 and C-like bands on other chromosomes. In this view, the authors suggest that structural modifications of the DNA, induced by acid fixation, can influence Hinf I activity on fixed metaphase chromosomes.