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.     

Restriction endonuclease/nick translation of fixed mouse chromosomes: A study of factors affecting digestion of chromosomal DNA in situ

We used a restriction endonuclease/nick translation procedure to study the ability of certain enzymes, known to cleave mouse satellite DNA in solution, to attack satellite DNA in fixed mouse chromosomes. Although AvaII and Sau96I readily attack the mouse major satellite in fixed chromosomes, BstNI and EcoRII do not normally do so, although if the heterochromatin is uncondensed as a result of culture in the presence of 5-azacytidine, BstNI can attack it. No clear evidence was obtained for digestion in situ of the minor satellite of mouse chromosomes by MspI, the only enzyme reported to cleave this satellite. Our results show that the DNA of mouse heterochromatin is not merely not extracted by certain restriction enzymes, but is actually not cleaved by them. Chromatin conformation is therefore shown to be an important factor in determining patterns of digestion of chromosomes by restriction endonucleases.by D. Schweizer     

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.     

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.     

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.     

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.     

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     

In situ nick translation of meiotic chromosomes to demonstrate homologous heterochromatin heterogeneity.

The in situ nick translation procedure performed on fixed meiotic chromosomes partially cleaved with restriction endonucleases shows a different staining of homologous heterochromatic regions, which could be explained through a differential restriction endonuclease cleavage. Mutations occurring before massive tandem duplication and involving those DNA motifs that produce these heterochromatic blocks, together with the absence of DNA recombination that characterizes these particular regions, could explain the observed results. This method for chromosome labelling is most useful to demonstrate a certain level of heterochromatin heterogeneity that is present in the genome of living species but remained cryptic to other techniques that are also able to induce longitudinal differentiation of the chromosomes.     

Reverse differential staining of sister chromatids induced by Hoechst plus black light and endonuclease

A differential Giemsa staining between sister chromatids was obtained by treating chromosomes replicated twice in medium containing 5-bromodeoxyuridine (BrdU) with Hoechst 33258 plus black light at 55 degrees C (HB pretreatment) and deoxyribonuclease (DNase) I, II, or micrococcal nuclease. In this staining pattern the BrdU bifilarly substituted chromatids were darkly and the unifilarly substituted chromatids lightly stained. This staining pattern was obtained only by staining the HB-DNase I-treated chromosomes with Giemsa and methylene blue, not by several other dyes tested. Relatively more DNA labelling was removed from the non-BrdU-substituted than the BrdU-substituted chromosomes, when the HB-pretreated chromosomes were digested with DNase I. But the protein labelling was not removed appreciably in the same treatment. The differential DNase I sensitivity between the non-BrdU-substituted and BrdU-substituted chromosomes disappeared when the HB-pretreated chromosomes were incubated with proteinase K before The DNase I digestion. Moreover, no differential DNase I sensitivity was found between the HB-pretreated isolated DNA containing and not containing BrdU. We propose that during the HB pretreatment, more DNA-protein cross-linkings are induced in BrdU bifilarly substituted than the unifilarly substituted chromatids. This structure protects the chromosomal DNA against the DNase I digestion. Thus, a reverse differential Giemsa staining between sister chromatids is obtained by the HB-DNase I treatment.     

The distribution of genes on human chromosomes as studied by in situ nick translation.

We have studied the distribution of potentially active genes on human chromosomes, using two methods: DNAse I hypersensitivity and restriction enzyme--nick translation with enzymes sensitive to methylation of CpG doublets. DNAse hypersensitivity is known to be associated with potentially active genes, and, when the reaction is detected by "in situ" nick translation, produces an R-banding pattern. Digestion of chromosomes with HpaII or CfoI, both of which should preferentially cut unmethylated sequences in the CpG islands associated with the majority of genes, also produces R-banding patterns. Deviations are attributable to overdigestion of the chromosomes, leading to extraction of DNA and loss of the specific sites that were to be detected. Contrary to the results of a number of previous workers, we have failed to demonstrate any differences between the DNAse I hypersensitivity or the degree of methylation of the active and inactive X chromosomes in metaphases from females.     

Analysis of methylation and distribution of CpG sequences on human active and inactive X chromosomes by in situ nick translation

In situ nick translation of fixed mitotic chromosomes after HpaII or MspI digestion allows us to detect different DNA methylation levels along chromosomes. We used this technique to analyse the methylation levels of CCGG sites in the active and inactive X chromosomes of female human cells. In addition, we analysed the distribution of these sites with respect to the banding pattern. Our data show that the inactive X, as a whole, is more methylated than the active one and that CCGG sequences are preferentially located on R-positive bands.     

Different DNA methylation pattern in A and B chromosomes of Crepis capillaris detected by in situ nick-translation. Comparison with molecular methods

Experiments were performed on Crepis capillaris callus lines with 0, 1 and 2 B chromosomes and on hairy root lines without or with 1 and 2 B chromosomes. Comparison of HPLC results for DNA from calli differing in number of B chromosomes did not reveal any significant differences in methylation level (30.4 +/- 1.1%, 30.9 +/- 1.2%, 31.7 +/- 1.7% in lines without or with one or two B chromosomes respectively) which could be attributed to the number of B chromosomes. Restriction patterns obtained after DNA digestion with HhaI, HpaII, MspI or HaeIII (i.e. restriction enzymes sensitive to cytosine methylation) were similar in calli and apical root segments and also did not depend on the presence or number of B chromosomes. Methylation of B chromosomes higher than that of A chromosomes was demonstrated by fluorescent in situ nick translation driven by HpaII, MspI or HaeIII in metaphase chromosomes. After short digestion (I and 3 h), B chromosomes, in contrast to A chromosomes, were weakly labelled or not labelled at all, which indicates longer distances between target sequences containing unmethylated cytosine in the former.     

Persistence of phage lambda DNA in genomes of mouse cells transformed by lambda-carrying SV40 vectors.

To test the suitability of simian virus 40 (SV40) DNA as a vector for inserting DNA segments into the chromosomes of mammalian cells, an EcoRI-A fragment of bacteriophage lambda DNA was covalently joined to a fragment of SV40 DNA and used to transform mouse cells in culture. Three independent, morphologically transformed clones were obtained that were positive for SV40 T-antigen by immunofluorescence staining. DNA from each transformant was examined by restriction enzyme analysis and found to contain both lambda and SV40 sequences. Co-migration of some fragments containing lambda and SV40 sequences following digestion of transformed cell DNA by each of four different restriction enzymes indicated that part of the retained lambda and SV40 DNA was linked in two of the three lines. In the third line, however, none of the restriction fragments had both lambda and SV40 sequences. Although the presence of non-integrated lambda DNA was not excluded, at least some of the lambda DNA appeared to be linked to host cell DNA. Results of digestion by EcoRI suggested that in some cases the transforming linear molecule had probably circularized prior to integration.     

Late replicating bands of human chromosomes demonstrated by fluorochrome and Giemsa staining.

The addition of thymidine (TdR) to cells growing in a medium containing 5-bromodeoxyuridine (BUdR) at the end of the first replication cycle results in the incorporation of TdR into the late replicating DNA regions. These sites can be visualized by staining the metaphase chromosomes with the fluorescent dye "33258 Hoechst" or a "33258 Hoechst" Giemsa procedure. A sequence of late replication patterns has been established in metaphase chromosomes of cultured human peripheral lymphocytes. The patterns are in agreement with those obtained by the standard autoradiographic procedures, but are more accurate. As is known from autoradiography, late replicating bands are in the position of G or Q bands. The "33258 Hoechst" Giemsa staining procedure of chromosomes which have replicated in the presence of BUdR first and in TdR for the last 2 hrs of the S phase is preferable to the currently used Giemsa banding techniques: the method yields very well banded metaphases in all preparations examined, as the chromosome structure is not disrupted by the pretreatment. The bands are very distinct, even in the "difficult" chromosomes (e.g. No. 4, 5, 8 and X). In female cells the late replicating X chromosome can be identified by its size and staining pattern. In addition to the replication asynchrony, the sequence of replication within both X chromosomes in female cells is not absolutely identical. The phenomenon of a phase difference in replication between the homologues is not a peculiarity of the X chromosome, but can be found in all autosomes as well as in homologous positions on the chromatids of individual chromosomes.     

The role of chromosomal proteins in the C-banding of Allium cepa chromosomes.

When chromosomes of Allium cepa are subjected to a C-banding procedure (incubation in saturated barium hydroxide followed by phosphate buffer at 60 degrees C for 1 h) and then treated with Giemsa stain, bands appear at the telomeres of all chromosomes. Microspectrophotometric measurements of Feulgen-DNA content, demonstrated that the C-banding procedure extracted DNA from the nuclei. Staining of banded chromosomes with several DNA-specific stains showed that this loss was differential, with the band DNA exhibiting more resistance to extraction than that of the rest of the chromosome. The C-banding procedure did not extract chromosomal proteins, however, and no difference in mass per unit length could be detected by Nomarski optics between band and interband regions. Several experiments demonstrated that chromosomal proteins play a significant role in C-banding. First, treatment of chromosomes with pronase before C-banding resulted in the elimination of differential staining with Giemsa. Furthermore, in preparations where the DNA was completely hydrolysed with hot TCA, the remaining chromosomal proteins were found to exhibit a differential affinity for Giemsa stain. Amido black staining demonstrated that total chromosomal protein was uniformly distributed after the hot TCA digestion, but the proteins localized in the telomeres had a greater affinity for the Giemsa stain than the bulk of the chromosomal proteins. When the TCA-digested chromosomes were subjected to the C-banding procedure before staining, the differential affinity of the telomeres for the Giemsa stain was lost. Thus, C-banding appears to be the result of a complex interaction between protein and DNA in which the greater resistance to extraction of the band DNA is necessary to stabilize and preserve chromatin protein which exhibits a differential affinity for Giemsa stain.     

In situ nick translation distinguishes between C-band positive regions on mouse chromosomes

In situ nick translation of mouse metaphase chromosomes by non-radioactive detection means and DNase I digestion followed by Giemsa staining were used to analyse the DNase I resistance of two different C-band positive regions. These were the centromeric heterochromatin of aero- and metacentric chromosomes and an interstitial C- band on chromosome 1 of wild mice, IS(HSR;1C5D)1Lub. Whereas the centromeric heterochromatin was clearly resistant to DNase I, the interstitial C-band showed very high DNase I sensitivity. Among centromeric C-bands, the heterochromatin in Robertsonian fusion biarmed chromosomes was more resistant to DNase I action than was the centromeric heterochromatin of the acrocentric chromosomes.     

S1 nuclease removes DNA from eukaryotic metaphase chromosomes: cytological evidence

Fixed and unfixed human chromosomes, as well as fixed rye chromosomes were treated with S1 nuclease, which specifically cleaves single stranded DNA. Subsequent staining with either acridine orange, ethidium bromide or Giemsa revealed that, contrary to what has previously been reported, S1 digestion extensively altered chromosomal morphology and staining intensity, although the alteration was more pronounced in fixed as compared to unfixed metaphases. A number of mechanisms, which may account for our findings, have been invoked: a) the presence in metaphase chromatin of B-DNA/Z-DNA transitional junctions, b) the induction, by alcohol: acid fixation procedure, of nicks within regular B-DNA conformation and c) the induction of sites available to S1 by torsional stress due to metaphase high condensation degree.     

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.     

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.