The role of chromosomal proteins in the induction of a differential staining of sister chromatids by light

Summary Fixed chromosomes of human lymphocytes, cultured in the presence of bromodeoxyuridine (BrdU) during two cell cycles, were exposed to near-ultraviolet irradiation, stained with Giemsa, and after destaining, were subjected to either Coomassie Blue or Feulgen-Schiff staining. A differential reaction of sister chromatids was first revealed by Coomassie Blue staining. Differential staining with Giemsa required a longer irradiation time. This appeared to be reduced after the addition of dithiodipyridine to the cells during their last few hours of culture. The differential pattern obtained after Coomassie Blue staining was the inverse of that obtained after Giemsa staining. From these findings we concluded that the induction of sister chromatid differentiation by light in BrdU-substituted DNA containing chromosomes occurs primarily via chromosomal proteins, presumably by differential breakage of their disulphide bonds. The results of the Feulgen-Schiff staining indicated that differential depurination of BrdU-containing DNA could occur, although only after very prolonged irradiation. A faint though distinctly differential Feulgen-Schiff pattern of sister chromated staining, resulting from differential removal of DNA, was observed after photosensitization by specific DNA-binding dyes. Thus, DNA seems to be affected only under more extreme conditions.     

Effects of acetic acid-alcohol,trypsin, histone 1 and histone fragments on Giemsa staining patterns in chromosomes

Summary In an effort to minimize subjective bias, a classification scheme was devised to assess Giemsa staining patterns obtained with experiments involving acetic acid-alcohol and exogenously applied histone 1 and polypeptides. A single rinse of metaphase preparations with acetic acid-alcohol quantitatively reduced Giemsa dye binding. Acid-alcohol irrversibly changed the conformation of HI and its ability to interfere with trypsin G-banding. Our results suggest that, in addition to protein extraction, acid-alcohol may alter the conformation of acid-insoluble components of metaphase chromosomes. The carboxy-terminal polypeptide (residues 73–212) from NBS cleavage of H1 was an effective inhibitor of Giemsa staining and trypsin G-banding. However, this polypeptide which is preferential for supercoiled DNA was much less efficient in inhibiting Giemsa staining of trypsinized metaphase chromosomes. The molecular consequences of these experiments are discussed.     

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

Summary 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 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.     

Light and scanning electron microscopic observations on the two contrasting types of sister chromatid differential staining after ultraviolet light irradiation

Chinese hamster cells were grown with 50 M 5-bromodeoxyuridine (BrdU) during the penultimate S phase to obtain chromosomes with the TB-TT chromatid constitution. Chromosome preparations made by the air-drying method were used to study the sister chromatid differential staining (SCD) resulting from ultraviolet (UV) irradiation followed by Giemsa staining by light and scanning electron microscopy (SEM). When chromosomes irradiated with UV light (253.7 nm, 5.2 J/m²/s) for more than 5 h were stained with 1% to 4% Giemsa in phosphate buffered saline (PBS) or in distilled water, the resulting SCD invariably belonged to the B-light type in which the TB-chromatid stained lightly. SEM observations of these chromosomes suggested that the B-light SCD was due to the selective photolysis of the TB-chromatid. On the other hand, when chromosomes were irradiated for only 10 min, and stained with 1% Giemsa in PBS, they showed a B-dark type SCD in which the TB-chromatid stained darkly. However, when chromosomes irradiated for 10 min were stained with 4% Giemsa in PBS or 1% Giemsa in distilled water, the resulting SCD again belonged to the B-light type. These findings indicate that when the irradiation dose is small, the resultant SCD is not a simple reflection of selective photolysis in the TB-chromatids and the type of SCD depends not only on the concentration of Giemsa but also on the salinity of the staining solution.     

An investigation of the mechanism of the reciprocal differential staining of BUdR-substituted and unsubstituted chromosome regions.

After treatment with hot NaH₂PO₄ at pH 9, BUdR-substituted and unsubstituted chromosome regions are palely and intensely stained with Giemsa, respectively; however, after treatment with the same solution at pH 4, the reciprocal staining patterns are produced, i.e. these chromosome regions are intensely and palely stained, respectively. The nature of the mechanisms responsible for this reciprocal differential Giemsa staining of BUdR-substituted and unsubstituted chromosome regions has been investigated by Feulgen staining, electron microscopy, and radioisotope analyses involving scintillation counting and autoradiography. The results indicate that different mechanisms are responsible for the two types of staining effect. The high pH NaH₂PO₄ treatment preferentially extracts BUdR-substituted DNA into the treatment solution, relative to unsubstituted DNA. The collective evidence from this and other work suggests that BUdR-substituted DNA in the chromosomes is partially photolysed by exposure to daylight during the harvesting procedure, and the degraded DNA is subsequently solubilized and extracted during the high pH treatment. This quantitative reduction of DNA in the BUdR-substituted chromosome regions results in pale Giemsa staining of these regions. The low pH NaH₂PO₄ treatment does not produce a significant extraction of either BUdR-substituted or unsubstituted DNA into the treatment solution; rather, there may be a redistribution of the unsubstituted DNA relative to the BUdR-substituted DNA such that the unsubstituted DNA is preferentially dispersed outside the boundaries of the chromosomes onto the surrounding area of the slide. It is suggested that the BUdR-substituted chromosome regions stain relatively intensely with Giemsa after the low pH treatment because the DNA in these regions is less dispersed than that in the unsubstituted regions.     

Involvement of sulfhydryl groups of chromosomal proteins in sister chromatid differentiation

The fluorescence of human lymphocyte chromosomes stained with sulfhydryl group-specific fluorochromes is markedly enhanced by a mild near-ultraviolet irradiation pretreatment, indicating breakage of protein disulfide bonds. When metaphase preparations of cells cultured in the presence of BrdU during two cell cycles are irradiated and subsequently stained with the sulfhydryl group-specific fluorescent reagents used in this study, a differential fluorescence of sister chromatids is observed. After staining with the DNA-specific fluorochrome DAPI an opposite pattern of lateral differentiation appears. It can be concluded that the chromatid containing bifilarly BrdU-substituted DNA has a higher content of sulfhydryl groups than the chromatid containing unifilarly BrdU-substituted DNA. This implies a more pronounced effect of breakage of disulfide bonds in the chromatid with the higher degree of BrdU-substitution. BrdU-containing chromosomes pretreated with the mild near-ultraviolet irradiation procedure used by us, do not show any differentiation of sister chromatids after Feulgen staining. Using sulfhydryl group-specific reagents, differential fluorescence of sister chromatids could still be induced by irradiation with near-ultraviolet light after the complete removal of DNA from the chromosomes by incubation with DNase I. Thus, the protein effect of irradiation of BrdU-containing chromosomes takes place independently of what occurs to DNA.Our results indicate that subsequent to the primary alteration of chromatin structure caused by the incorporation of BrdU into DNA, breakage of disulfide bonds of chromosomal proteins might play an important role in bringing about differential staining of sister chromatids, at least for those procedures that use irradiation as a pretreatment or prolonged illumination during microscopic examination.     

A method for combined C-banding and silver staining

A reliable technique for combined C-banding and silver staining of metaphase chromosomes which uses trypsinization is described. Slides are first immersed in dilute HCl to remove residual cytoplasm from around the chromosomes. They are then treated with saturated barium hydroxide and incubated overnight in saline sodium citrate (0.30 M NaCl, 0.03 M sodium citrate, adjusted to pH 7.0 with HCl). Following the C-banding pretreatment, a two-step method of silver staining which employs a protective colloidal developer is used to stain the nucleolar organizer regions (NORs) of the chromosomes. Silver staining is followed by trypsinization to remove extraneous silver precipitate from the chromosome arms which permits the C-bands to be stained with Giemsa. The method works equally well with fresh and aged mitotic chromosome preparations and gives consistent staining of both heterochromatin and active NORs in metaphases across the slide.     

A Method for Combined C-Banding and Silver Staining

A reliable technique for combined C-banding and silver staining of metaphase chromosomes which uses trypsinization is described. Slides are first immersed in dilute HCl to remove residual cytoplasm from around the chromosomes. They are then treated with saturated barium hydroxide and incubated overnight in saline sodium citrate (0.30 M NaCl, 0.03 M sodium citrate, adjusted to pH 7.0 with HCl). Following the C-banding pretreatment, a two-step method of silver staining which employs a protective colloidal developer is used to stain the nucleolar organizer regions (NORs) of the chromosomes. Silver staining is followed by trypsinization to remove extraneous silver precipitate from the chromosome arms which permits the C-bands to be stained with Giemsa. The method works equally well with fresh and aged mitotic chromosome preparations and gives consistent staining of both heterochromatin and active NORs in metaphases across the slide.     

Stabilization of chromosomes by DNA intercalators for flow karyotyping and identification by banding of isolated chromosomes

A number of structurally unrelated DNA intercalators have been studied as stabilizers of mitotic chromosomes during isolation from rodent and human metaphase cells. Seven out of the nine intercalators tested were found to be useful as chromosome stabilizing agents. Chromosome suspensions prepared in this way could be preserved for long periods of time. After isolation the chromosomal DNA was longer than 150 kb. With intercalated chromosomes high resolution flow karyotypes could be obtained as illustrated for the non-fluorescent intercalators 9-methylene-(1,3-dimethyl-2,4-dionepyrimidine-5-yl)-phenanthrid in iumchloride and 4'-aminomethyl-4,5', 8-trimethylpsoralen combined with DAPI and 33258 Hoeschst for fluorescent staining and for the fluorescent intercalator propidium iodide used as a stabilizer and as a fluorochrome. Passage of the intercalated chromosomes through the laser beam had no measurable effect on the length of the chromosomal DNA subsequently isolated. After flow analysis and collection on slides human chromosomes could easily be banded by Giemsa staining methods with the same resolution as obtained in conventional metaphase spreads. This allowed a ready identification of about 80 percent of all chromosomes in the unfractionated suspension collected after passage through the laser beam.     

Comparative analysis of micro and macro B chromosomes in the Korean field mouse Apodemus peninsulae (Rodentia, Murinae) performed by chromosome microdissection and FISH

Comparative analysis of micro B and macro B chromosomes of the Korean field mouse Apodemus peninsulae, collected in populations from Siberia and the Russian Far East, was performed with Giemsa, DAPI, Ag-NOR staining and chromosome painting with whole and partial chromosome probes generated by microdissection and DOP-PCR. DNA composition of micro B chromosomes was different from that of macro B chromosomes. All analyzed micro B chromosomes contained clusters of DNA repeats associated with regions characterized by an uncondensed state in mitosis. Giemsa and DAPI staining did not reveal these regions. Their presence in micro B chromosomes led to their special morphology and underestimation in size. DNA repeat clusters homologous to DNA of micro B chromosome arms were also revealed in telomeric regions of some macro B chromosomes of specimens captured in Siberian regions. Neither active NORs nor clusters of ribosomal DNA were found in the uncondensed regions of micro B chromosomes. Possible evolutionary pathways for the origin of macro and micro B chromosomes are discussed.     

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.     

Evaluation of the nuclear DNA Diffusion Assay to detect apoptosis and necrosis

We applied the nuclear DNA Diffusion Assay, described as an accurate tool to estimate apoptotic and necrotic cells [N.P. Singh, A simple method for accurate estimation of apoptotic cells, Exp. Cell Res. 256 (2000) 328-337] to tobacco root and leaf cells. In this assay, isolated nuclei are embedded in an agarose microgel on a microscope slide and low molecular-weight DNA fragments diffuse into the microgel. Exposure of the roots to hydrogen peroxide significantly increased the average nuclear area of isolated nuclei. After 4 and 24 h of recovery, all DNA damage was repaired. The data clearly demonstrate that the manifestation of diffused nuclei upon exposure to hydrogen peroxide is not the result of non-repairable apoptotic or necrotic DNA fragmentation, but represents repairable genotoxin-induced DNA damage. In contrast, treatment with the alkylating agent ethyl methanesulphonate (EMS) followed by 24 h of recovery produced a significant increase in the average nuclear area. The contribution of apoptosis to this increase cannot be excluded. Heat treatment of leaves at 50 degrees C for 1-15 min leading to necrosis, and treatment of isolated nuclei with DNase-I, which digests DNA to nucleosome-sized fragments as during apoptosis, also led to a dose-dependent increase in the nuclear area. The use of different fluorochromes (ethidium bromide, DAPI or YOYO-1) for DNA staining yielded similar results in the DNA Diffusion Assay. As all types and sizes of diffused nuclei were observed after EMS and hydrogen peroxide treatments, we were unable to differentiate, on the basis of the structure of the nuclei, between apoptotic or necrotic DNA fragmentation and other types of genotoxin-induced DNA damage in plants.     

Studies on the Mitotic Prophase Chromosomal Fibers in Vicia faba

The observations have been made on the structures of mitotic prophase nuclei and chromosomes in Vicia faba root meristematic cells. Two methods, i.e., the cell squashing and the nucleus isolation methods, were applied in present study to prepare the specimen of chromosomes and nuclei. Chromosomal fibers 0.3—0.5 μm in diameter were observed in the squashed preparations stained with Giemsa, and in the isolated nucleus preparations treated with 0.05% EDTA followed by Giemsa staining. Using Feulgen reaction, it has been demonstrated that these fibers are nuclear origin containing DNA. The results suggest that this order of chromosomal fiber may be one structural level in the chromosomes in Vicia faba. This conclusion is in support of the view which holds that there exists an intermediate level of structure between the 250–300Å chromatin fiber and the chromosome.     

Characterization of DNA damage in yeast apoptosis induced by hydrogen peroxide, acetic acid, and hyperosmotic shock

Saccharomyces cerevisiae has been reported to die, under certain conditions, from programmed cell death with apoptotic markers. One of the most important markers is chromosomal DNA fragmentation as indicated by terminal deoxynucleotidyl transferase dUTP nick-end labeling (TUNEL) staining. We found TUNEL staining in S. cerevisiae to be a consequence of both single- and double-strand DNA breaks, whereas in situ ligation specifically stained double-strand DNA breaks. Cells treated with hydrogen peroxide or acetic acid staining positively for TUNEL assay stained negatively for in situ ligation, indicating that DNA damage in both cases mainly consists of single-strand DNA breaks. Pulsed field gel electrophoresis of chromosomal DNA from cells dying from hydrogen peroxide, acetic acid, or hyperosmotic shock revealed DNA breakdown into fragments of several hundred kilobases, consistent with the higher order chromatin degradation preceding DNA laddering in apoptotic mammalian cells. DNA fragmentation was associated with death by treatment with 10 mM hydrogen peroxide but not 150 mM and was absent if cells were fixed with formaldehyde to eliminate enzyme activity before hydrogen peroxide treatment. These observations are consistent with a process that, like mammalian apoptosis, is enzyme dependent, degrades chromosomal DNA, and is activated only at low intensity of death stimuli.     

Quick and Reversible Staining Methods for G- and Q-Bands of Chromosomes

Staining G-bands of chromosomes can be carried out in 2 minutes using a mixture of Giemsa solution with a special diluting preparation. The staining is completely reversible without any damage to the chromosomes. Moreover, an improved method for staining Q-bands with atebrin and mounting the preparation in sucrose is described. The whole process is performed in one minute and the preparations keep for weeks at laboratory temperature.     

Reverse differential staining of sister chromatids after substitution with BUdR and incubation in sodium phosphate solution

Chinese hamster strain cells were cultured in the presence of BUdR and air-dried on slides. The chromosome preparations were incubated in 1 M NaH₂PO₄ at 88 °C for 4–6 min and stained with Giemsa. The reverse type of sister chromatid differential staining occurred, in which unifilarly BUdR-substituted chromatids stained faintly and bifilarly substituted chromatids stained darkly. Feulgen reaction performed on the same chromosomes after removing Giemsa stain showed the same type of differential staining.     

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.     

Rapid irradiation procedure for obtaining permanent differential staining of sister chromatids and aspects of its underlying mechanism

Summary When fixed metaphase preparations of lymphocytes cultured in the presence of BrdU during two cell cycles are subjected to a 1-min simple irradiation treatment with near-ultraviolet light (radiation dose 3×10⁵ J/m²), subsequent Giemsa staining produces differential staining of sister chromatids irrespective of previous exposure to a photosensitizer. The effects of this procedure were analyzed by irradiating single metaphases under the microscope, thus allowing precise dosage of radiation: Metaphase were subsequently stained with Giemsa and then subjected to the Feulgen-Schiff procedure. Whereas in the presence of DAPI as a photosensitizer a differential breakdown of BrdU-containing DNA in the chromatids under the influence of irradiation appeared to be the cause of sister chromatid differentiation, alterations presumably in the higher oeder structure of chromatin, not accompanied by removal of DNA, induced sister chromatid differentiation without DAPI.     

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.     

Mechanism of differential staining of BUdR-substituted Vicia faba chromosomes.

Chromosomes of the broad bean Vicia faba were isolated and air-dried on slides after incorporation of BUdR into DNA (BUdR substitution) for two rounds of replication. Then the preparations were embedded in a buffer solution containing trypsin as well as fluorescence dye (acridine orange or Hoechst 33258). We observed chromosomes with a fluorescence microscope at various times after embedding. After about 15 min one sister chromatid of some of the metaphase chromosomes showed enhanced darkening and disintegration within 1–4 min (melting effect) during observation. We suppose that fragmentation of BUdR-substituted DNA by the acridine orange-visible light system in acridine orange staining and by irradiation with wavelengths around the transition from UV to visible light in Hoechst 33258 staining is responsible for this phenomenon. The disintegration of one sister chromatid in BUdR-substituted chromosomes can also be produced by UV irradiation during trypsin treatment when fluorescence dyes are not present.