Sister chromatid exchanges in barley

Summary A mean frequency of 20.6 sister chromatid exchanges (SCEs) per cell has been observed in a reconstructed karyotype of Hordeum vulgare by application of the FPG technique after unifilar incorporation of BrdU into chromosomes. The involvement in SCEs of the 48 segments into which the chromosome set had been subdivided was, with a single deviation, length proportional and independent of the segment's heterochromatin content. Asymmetric bands, indicative of an uneven distribution of adenine and thymidine between the DNA strands in adenine (A)-thymidine (T) rich chromosome regions, could not be detected after incubation of the cells in BrdU for one cycle of DNA replication.     

On the Quinacrine fluorescence and Giemsa staining patterns of the chromosomes of Vicia faba

Abstract

A comparison has been made between the Quinacrine fluorescence bands and the bands obtained with a denaturating-reannealing-Giemsa technique in Vicia faba. The results show that some of the bands, particularly on the M and, proximally, on the S chromosomes are visible with both techniques. A complex pattern of bands on the S chromosomes is revealed with the Giemsa technique. Both the similarities and the differences between the banding patterns obtained with the two methods in Vicia faba may indicate various degrees of DNA repetitiousness and other physico-chemical properties in the chromosome segments involved.     

The effect of continuous gamma irradiation on formation of sister chromatid exchanges (SCEs) and chromosomal aberrations in meristematic cells ofVicia faba

Germinated seeds ofVicia faba were continuously irradiated at low dose rate of gamma rays (0.05 Gy h-¹) up to a total accumulated dose of 2 Gy. The FPG (fluorescence plus Giemsa) technique of differential chromatid staining was used to monitor the frequency of sister chromatid exchanges (SCEs) in irradiated root tip meristem cells. The results of the experiments have demonstrated that SCE frequency is raised by continuous gamma irradiation only in plant cells containing BrdU in the chromosomal DNA. No effect concerning SCE formation was recorded at continuous irradiation of meristematic cells of Vicia faba with native, i. e. BrdU-nonsubstituted, DNA. In contrast to SCEs, a significant increase was found in the yield of chromosomal aberrations in all variants of irradiation.     

The influence of incorporated bromodeoxyuridine on mutagenicity testing by sister chromatid exchange induction inVicia faba root tip cells

The induction of sister chromatid exchanges (SCEs) inVicia faba root-tip cells after short-term (2 h) and long-term (24 h) treatments with alkylating agents (N-methyl-N-nitrosourea, ethyl methanesulphonate) and maleic hydrazide was studied. The primary roots were treated with mutagens before or after 5-bromodeoxyuridine (BrdU) incorporation into DNA and the influence of mutagen application on SCE induction in the cells with non- and BrdU-substituted chromosomal DNA. On the contrary, application of maleic hydrazide after the incorporation of BrdU into DNA strongly increased the rate of SCEs. The lowest limit concentrations of mutagens capable of significantly increasing SCE frequency in the cells with non-substituted DNA after the long-term treatment were estimated.     

The Giemsa banding patterns of the standard and four reconstructed karyotypes of Vicia faba

The Giemsa banding patterns of the standard karyotype of Vicia faba and of four new karyotypes with easily interdistinguishable chromosomes due to interchanges and inversions are described and compared with the data of other authors on preferential Giemsa staining in Vicia faba. All karyotypes contain 14 easily reproducible marker bands which characterize chromosome segments known to be heterochromatic. It is shown that the preferential Giemsa staining of chromosome regions is a valuable tool for the localization of translocation and inversion points in the chromosomes of the reconstructed Vicia karyotypes. A close correlation exists between banding patterns, segment extension by incorporation into chromosomal DNA of azacytidine and mutagen-specific clustering of induced chromatid aberrations in the new karyotypes.     

BrdU related direct revelation of typical dynamic R- and G-banding with the use of monoclonal anti-BrdU antibody.

Pulse 5-bromodeoxyuridine (5-BrdU) incorporation during the last S-phase is known to produce R- or G-banded chromosomes after photolysis-plus-Giemsa (FPG) staining. The authors applied an immunological staining with monoclonal anti-BrdU antibody instead of the FPG protocol. The results offered banded chromosomes with an immunological typical R-banding (RBI) on the GBG cultivated cells (early pulse incorporation), and an immunological G-banding (GBI) on the RBG cultivated ones (late pulse incorporation). After a further FPG protocol following an immunological treatment, an inverted banding pattern became evident whereas a faint immunological staining remained. Thus the method superimposed a GBG-banding on the RBI-staining or a RBG on the GBI one. This allows a rapid and easy R and G double chromosomal identification on the same metaphase cell, using first the immunological banding then the classical FPG staining. The method allows a reproducible dynamic G-banding with an easy monitored late 5-BrdU pulse incorporation specially attractive in spontaneous dividing cells from bone marrow. This dynamic G-banding protocol should be extended to chorionic villi and malignant cells. Our data are in agreement with a connection between dynamic banding and chromosomal portions containing or not BrdU. The lack of an immunological staining after the FPG protocol has been noticed and assume the photolysis degradation-elution of the DNA in BrdU-substituted areas.     

Effect of 5-bromodeoxyuridine substitution on sister chromatid exchange induction by chemicals

The fluorescence-plus-Giemsa (FPG) technique for analysis of sister chromatid exchange (SCE) is widely used as an assay for mutagenic carcinogens. There is very little information, however, on whether incorporation of the bromodeoxyuridine (BrdU) necessary for visualization of SCEs affects the sensitivity of the SCE test system to different chemical agents. We have investigated the effect of BrdU incorporation on SCE induction by labeling cells with BrdU for either the first cell cycle or the first and second cell cycles. The cells were then treated with bleomycin, which produces DNA strand breakage; proflavine, which intercalates into DNA; mitomycin C, which produces monoadducts and DNA crosslinks; or aphidicolin, which inhibits DNA polymerase . Chemicals were added before BrdU exposure or during the first, second, or both cell cycles. Only mitomycin C, which induces long-lived lesions, elevated the SCE frequency when cells were treated before BrdU labeling. When bleomycin, proflavine, or mitomycin C was present concurrently with BrdU, the frequency of SCEs was increased independently of the BrdU labeling protocol. Aphidicolin, on the other hand, induced more SCEs when present for the second cell cycle, when DNA replicates on a template DNA strand containing BrdU. We also examined the induction of SCEs in the first cell cycle (twins) and in the second cell cycle (singles) after continuous treatment of cells with BrdU and the test chemicals. Only aphidicolin increased SCE frequency in the second cell cycle. These results indicate that aphidicolin, but not bleomycin, proflavine, or mitomycin C, affects BrdU-substituted DNA and unsubstituted DNA differently. This type of interaction should be taken into consideration when the SCE test is used as an assay system.     

家蚕染色体复制区带的初步显示

该文采用家蚕Bomoyx mori活体注射BrdU结合FPG(fluorochrome photolyusis Giem-sa)显带方法,以生殖腺为材料,成功显示出家蚕有丝分裂中期染色体复制带。由于处于S-期的细胞有早有晚,且同一细胞DNA各片段的复制亦有先后,因此BrdU掺入DNA合成的时间也有所不同,从而可产生出早、中、晚复制带型。BrdU掺入时间早,则会在家蚕部分染色体上出现大面积浅染带纹的早复制带。每一染色体皆有其独特的带纹特征,据此可初步将它与其它染色体相互区分;随着BrdU掺入时间的推后,染色体上会出现深浅交替、丰富的带纹,即中复制带型;至S-期DNA合成晚期掺入BrdU,最终染色体出现以深染带纹为主,浅染带纹仅出现于少数染色体的中部、近中部或端部的晚复制带。     

Cell synchronization and dynamic G-banding of equine chromosomes by bromodeoxyuridine

Both dynamic G-banding and cell synchronization produced by bromodeoxyuridine (BrdU), were applied to equine chromosomes. BrdU incorporated during the first half of the S-phase is taken up into the R-bands that are early replicating. These bands, which have incorporated BrdU, cannot contract as usual and remain elongated; only the other regions of the chromosome, i.e., the G-bands, contract normally and are sharply defined. BrdU also can be used for cell synchronization. The addition of BrdU in a high concentration, 15 hours before harvest, and its removal 11 hours later, has two effects: initially the BrdU is incorporated during the first part of the S-phase and then it blocks the cells at mid-S-phase. Within the cell cycle, mid-S-phase appears to be the most vulnerable time to various blocking agents. To differentiate the regions of BrdU incorporation from those that have not been substituted, the fluorescence-photolysis-Giemsa (FPG) technique was applied as modified for horse chromosomes. This dynamic technique, which produces many prometaphase and prophase chromosomes showing very sharp G-bands, is certain to enhance the accuracy of cytogenetic analysis and aid in the standardization of equine chromosomes.     

Cell cycle analysis in a multinucleate green alga,Boergesenia forbesii (Siphonocladales,Chlorophyta)*

The cell cycle (nuclear division cycle) of a multinucleate green alga, Boergesenia forbesii (Harvey) Feldmann was studied using microspectrophotometry and BrdU incorporation techniques. Mitosis was observed frequently 1-4 h after the beginning of the light period, on a 16:8 h LD cycle at 25°C. Mitotic nuclei formed discrete patches. Other nuclei remained in the G₁ period. The DNA synthetic phase (S phase) was estimated to last about 12 h from microspectrophotometric study using aphidicolin inhibition just before the S phase and release from it. The G₂ period was estimated to be about 2 h, because a labeled prophase nucleus could be detected when the samples were labeled with BrdU continuously over 3 h. The incorporation pattern of BrdU changed through the S phase nucleus. In early S phase, BrdU staining was detected as many dots in the entire nucleus, while in late S phase, it was detected as several discrete regions along the nuclear membrane. Almost all nuclei in B. forbesii were in the G₁ stage after nuclear division, and the nuclei in several patches of the cell simultaneously initiated DNA synthesis. Once the nuclei entered into S phase, these nuclei continued into G₂ and mitosis. In other words, the cell cycle regulation of entrance into S phase from G₁ is an important factor in the growth and morphogenesis in B. forbesii.     

Cytological demonstration of DNA synthesis inhibition at late S by 5-amino-uracil

Meristematic cells of Allium cepa were treated with 5-amino-uracil (5-AU) while incorporating 5-bromodeoxyuridine (BrdU) into DNA until complete inhibition of mitosis was obtained. The pattern of BrdU substitution in interphase nuclei detected by FPG technique in the cells so treated was that known as corresponding to BrdU incorporation in only early and middle replicating DNA. In addition, when the cells were allowed to reach mitosis in the absence of BrdU after the synchronization induced by 5-AU all the metaphase chromosomes showed, likewise, the typical late-replicating pattern. These results are a cytological demonstration of a preferential inhibition of late-replicating DNA synthesis by 5-AU proposed by several authors.     

Detailed cell cycle analysis in human lymphocytes; Application to γ-irradiated cells

Summary A method based on BrdU incorporation for analyzing in detail the kinetics of the cell cycle is described. The S phase has been subdivided into five subphases, each recognizable by their BrdU incorporation pattern at metaphase. The method can be useful for the study of abnormal cell cycles, and may have particular application in mutagenesis studies concerning the various subphases of the S phase, without using synchronization techniques. An application of the method is described, showing that -irradiation, during the course of the S phase, leads to a lack of cells which were in early S phase at the time of irradiation. This finding can be related either to a higher lethality at this stage of the cell cycle or to a delay in completion of DNA replication after irradiation.Hoider of a C.E.C. scholarship     

Factors influencing the frequency of mitomycin C-induced sister-chromatid exchanges in 5-bromodeoxyuridine-substituted human lymphocytes in culture.

Newly developed techniques for the detection of sister-chromatid exchanges (SCE) require the substitution of 5-bromodeoxyuridine (BrdU) for thymidine in DNA. We investigated the possibility of interactions between BrdU and one mutagen--carcinogen, mitomycin C (MMC) for the induction of both chromosomal aberrations and SCE in human peripheral lymphocytes in culture. No effect on aberration yield was found. Neither comparisons between the yields of SCE by BrdU substitution and differential staining and those detected by tritiated thymidine incorporation and autoradiography nor between the yields of SCE for different levels of BrdU incorporation provided any evidence of synergism. It was found, however, that MMC persists in cultures and continues to increase SCE frequencies for about 30 h. It was also observed that some MMC-induced DNA lesions persist long enough so that some of those present prior to S phase of the first cell cycle cause additional SCE in the third cycle.     

Cytological localization of fast renaturing and satellite DNA sequences inVicia faba

Summary DNA sequences reassociating within a Cot value of 1.8×10^–1 and those producing a light satellite in a CsCl density gradient were isolated fromVicia faba DNA and hybridizedin situ on squashes of roots of the same species. Silver grains were seen to be scattered over both the interphase nuclei and the metaphase chromosomes after hybridization with fast renaturing DNA sequences, indicating these are fairly regularly interspersed in theV. faba genome. Clustered labeling occurred after hybridization with satellite DNA sequences, indicating these are clustered in the genome. The localization of satellite DNA in chromosomes appeared to correspond closely to the position of the bright bands detectable after staining with quinacrine mustard. After hybridization with both DNA probes, labeling intensity over the nuclei of meristematic cells was higher than that over the nuclei of differentiating and/or differentiated cells. These results are discussed in relation to the structure of the cell nucleus, the mechanism of quinacrine banding and to previous data suggesting underrepresentation of nuclear repeated DNA sequences in differentiatingV. faba root cells.     

Cytophotometrical measurement of nuclear DNA content in some coniferous and deciduous trees

Summary The DNA content of nuclei from meristematic root tip cells of five coniferous and one deciduous tree species and, for comparison, ofVicia faba was cytophotometrically determined. The DNA values of diploid nuclei fromGinkgo biloba are approximately a quarter lower than those fromVicia faba. The nuclear DNA values of the other tree species are merely a third to a ninth part of those ofVicia faba. In three tree species, as well as diploid, we have found nuclei of different polyploid level.The reliability of different cytochemical methods, which are used for determination of the nuclear DNA content, is critically analyzed. The DNA values of the investigated tree species are discussed in connection with the evolution of the DNA content in higher plants.Dedicated to Professor Dr. F. Mechelke in honour of his 60th birthday     

The biochemical and cytological characterization of Vicia faba DNA by means of MboI,AluI and Bam HI restriction endonucleases

Summary Restriction endonucleases were employed to characterize both cytologically and electrophoretically the DNA of Vicia faba. The electrophoretic pattern of total DNA digested with AluI and MboI shows a continuous smear. Bam HI also shows a continuous smear for the bigger polynucleotide fragments and several bands in the lower part of the lane. Digestion of fixed chromosomal DNA produces metaphase longitudinal differentiation when MboI and AluI are used, while no appreciable banding pattern is present when Bam HI is employed. These results are discussed in relation to the organization of chromosomal DNA, to other data in the literature on chromosome banding and on the digestion of total DNA of other species.     

Characterisation of a very complex constitutive heterochromatin in two Gerbillus species (Rodentia)

A large amount of heterochromatin is observed in two species of the genus Gerbillus, G. nigeriae and G. hesperinus. The C-band material represents about one-half of the total karyotype length in the former species, and about one-third in the latter. Several banding techniques and various 5-bromodeoxyuridine (BrdU) treatments were used to characterise these heterochromatic segments. After applying the R-banding technique, three different staining responses of the heterochromatin can be distinguished. In G. nigeriae, strongly stained segments (R-band positive) appear in most chromosomes and, in particular, constitute the short arms of all the larger chromosomes. Palely staining heterochromatic segments (R-band negative) are less abundant in G. nigeriae but predominate in G. hesperinus. In addition, in both species an intermediate staining of heterochromatin is observed near the centromere or in the heterochromatic short arms of some acrocentric and small submetacentric chromosomes. Very short BrdU treatment during the end of the last cell cycle results in asymmetrical staining of chromatids in heterochromatic segments after applying the acridine orange or FPG (fluorescence plus Giemsa) technique. The alternating location of strongly staining segments in one or the other chromatid simulates sister chromatid exchanges (pseudo-SCE). This pattern persists after longer BrdU treatment during different stages of the last cell cycle and is independent of the R-staining properties of the heterochromatin. The lateral asymmetric appearance of the large heterochromatic segments in Gerbillus is interpreted as reflecting an uneven distribution of adenine and thymidine between the two strands of DNA.     

Distribution of heterochromatin in a reconstructed karyotype of Vicia faba as identified by banding- and DNA-late replication patterns

1) The distribution pattern of heterochromatin characterized by Giemsa-banding, Quinacrine-banding and DNA-late replication has been studied in a reconstructed karyotype of Vicia faba with all chromosome pairs interdistinguishable. 2) By means of two Giemsa-banding methods both an interstitial and a centromeric Giemsa-banding pattern are described. The former one comprehends 14 marker and 18 additional bands of lower but characteristic visualization frequencies. The centromeric Giemsa-banding pattern consists of 7 bands, located in the centromeric and in the secondary constrictions of the metaphase chromosomes. Chromosomes with banding patterns intermediate between the interstitial and the centromeric Giemsa-banding have also been observed. 3) Quinacrine-banding revealed 10–12 brightly fluorescent bands and 1–2 regions of dim fluorescence. Most Q-bands occupy chromosomal positions also characterized by interstitial Giemsa bands. 4) The DNA-late replication pattern, analyzed both by autoradiography and by FPG-technique, revealed 9 late replicating chromosome regions; all of these correspond positionally to the sites of interstitial Giemsa bands. 5) The results are discussed with respect to (a) the relationships between the banding- and the DNA-late replication pattern; (b) banding and heterochromatin characteristics; (c) the correlations between the distribution of chromatid aberrations and special types of heterochromatin. — The patterns of heterochromatin distribution found are in basic conformity with the corresponding patterns reported for the standard karyotype of Vicia faba. The heterochromatin type characterized by both Giemsabanding and late replication is characteristic of all those chromosome regions which after mutagen treatments show up as aberration hot spots. Positional correlations between interstitial Giemsa marker bands and chemically induced isochromatid breaks are indicative of preferential aberration clustering in heterochromatin/euchromatin junctions.