白桦愈伤组织化学诱变

用不同浓度的甲基磺酸乙酯(ethyl methane sulfonate, EMS)对白桦(Betula platyphalla Sak.)愈伤组织进行化学诱变处理。结果表明: EMS诱变剂的浓度和处理时间对愈伤组织的存活率有很大影响。在高浓度EMS短时间处理和低浓度EMS长时间处理条件下得到叶柄、叶片愈伤组织的半致死剂量。通过观察半致死剂量下愈伤组织的染色体发现, 诱变后细胞中单倍体、非整倍体及多倍体比例均高于对照, 这说明EMS的诱变处理引起了愈伤组织细胞中染色体数量的变化。     

Proliferative advantage of specific aneuploid cells drives evolution of tumor karyotypes

Most tumors have abnormal karyotypes, which arise from mistakes during mitotic division of healthy euploid cells and evolve through numerous complex mechanisms. In a recent mouse model with increased chromosome missegregation, chromosome gains dominate over losses both in pretumor and tumor tissues, whereas T-cell lymphomas are characterized by gains of chromosomes 14 and 15. However, the quantitative understanding of clonal selection leading to tumor karyotype evolution remains unknown. Here we show, by introducing a mathematical model based on a concept of a macro-karyotype, that tumor karyotypes can be explained by proliferation-driven evolution of aneuploid cells. In pretumor cells, increased apoptosis and slower proliferation of cells with monosomies lead to predominant chromosome gains over losses. Tumor karyotypes with gain of one chromosome can be explained by karyotype-dependent proliferation, whereas, for those with two chromosomes, an interplay with karyotype-dependent apoptosis is an additional possible pathway. Thus, evolution of tumor-specific karyotypes requires proliferative advantage of specific aneuploid karyotypes.     

The induction of aneuploidy by nitrogen mustard in a human lymphoblastoid cell line

We report that the presence of an extra Y chromosome can be used as a marker for the induction of aneuploidy (mitotic non-disjunction) in a human lymphoblastoid cell line. This endpoint is easily visualized in metaphase chromosome preparations after staining with quinacrine mustard. The induction of cells with two Y chromosomes by nitrogen mustard (NM) was examined. Exposure to 150 ng/ml nitrogen mustard induced a 6-fold increase in aneuploid frequency relative to untreated control levels; maximal induction of aneuploidy was observed 2 days after treatment. Lower concentrations of nitrogen mustard (36 and 75 ng/ml) induced smaller increases in aneuploid frequency, with maximal induction observed 1 day after treatment. This system has the potential to be used as an assay for the induction of aneuploidy in cultured human cells.     

Indirect mitotic nondisjunction in Vicia faba and Chinese hamster cells

The hypothesis of indirect mitotic nondisjunction was tested in plant and mammalian cells. This hypothesis states that micronuclei derived from lagging chromosomes or chromatids are able to perform DNA synthesis and undergo mitotic condensation synchronously with main nuclei. Hence, as chromosomes, they can be moved to spindle poles together with the chromosomes of the main nuclei during mitosis. In that way chromosomes lost as micro-nuclei can be reincorporated in the main nuclei. In order to test this, both Vicia faba meristematic cells and cells of a Chinese hamster line (Cl-1) were treated with low doses of colchicine. Mitotic anomalies, micronuclei and cells with a polyploid or aneuploid karyotype were scored at different fixation times. A detailed analysis was performed on single chromosome misdistributions, as well as on micronuclei and cells with aneuploid karyotypes derived from single chromosome misdistributions. Indirect mitotic nondisjunction was shown to play a primary role in the origin of aneuploid karyotypes in Vicia faba, but not in Cl-1 cells.     

Retinoic acid-treated pluripotent stem cells undergoing neurogenesis present increased aneuploidy and micronuclei formation

The existence of loss and gain of chromosomes, known as aneuploidy, has been previously described within the central nervous system. During development, at least one-third of neural progenitor cells (NPCs) are aneuploid. Notably, aneuploid NPCs may survive and functionally integrate into the mature neural circuitry. Given the unanswered significance of this phenomenon, we tested the hypothesis that neural differentiation induced by all-trans retinoic acid (RA) in pluripotent stem cells is accompanied by increased levels of aneuploidy, as previously described for cortical NPCs in vivo. In this work we used embryonal carcinoma (EC) cells, embryonic stem (ES) cells and induced pluripotent stem (iPS) cells undergoing differentiation into NPCs. Ploidy analysis revealed a 2-fold increase in the rate of aneuploidy, with the prevalence of chromosome loss in RA primed stem cells when compared to naïve cells. In an attempt to understand the basis of neurogenic aneuploidy, micronuclei formation and survivin expression was assessed in pluripotent stem cells exposed to RA. RA increased micronuclei occurrence by almost 2-fold while decreased survivin expression by 50%, indicating possible mechanisms by which stem cells lose their chromosomes during neural differentiation. DNA fragmentation analysis demonstrated no increase in apoptosis on embryoid bodies treated with RA, indicating that cell death is not the mandatory fate of aneuploid NPCs derived from pluripotent cells. In order to exclude that the increase in aneuploidy was a spurious consequence of RA treatment, not related to neurogenesis, mouse embryonic fibroblasts were treated with RA under the same conditions and no alterations in chromosome gain or loss were observed. These findings indicate a correlation amongst neural differentiation, aneuploidy, micronuclei formation and survivin downregulation in pluripotent stem cells exposed to RA, providing evidence that somatically generated chromosomal variation accompanies neurogenesis in vitro.     

Cytogenetic effects of the addition of leukocytes and blood sera on human fibroblasts exposed to measles virus or to streptolysin-O

Infection with measles virus and also introduction of streptolysin-O induced a significant increase in the level of cells with cytogenetic disturbances in the culture of human fibroblasts (HF). A decrease to intact condition of the number of HF with aneuploid and polyploid sets of chromosomes was observed after the introduction of non-immune autologous T-lymphocytes into the cultures. Immune homologous T-lymphocytes, unlike non-immune autologous T-lymphocytes, eliminated cells with structural disturbances of the chromosomes from the culture, but did not influence the level of aneuploid and polyploid cells. The ability of immune T-lymphocytes to exert antimutagenic effect can obviously be explained by their cytolytic action on virus-infected cells. As for non-immune autologous T-lymphocytes, two ways are equally probable: T-lymphocytes eliminate HF with virus antigens on their surface, or T-lymphocytes determine and destroy fibroblasts with changed cell surface developing as a result of cytogenetic disturbances induced by infectious factors. Specificity of the cytolytic reaction of T-lymphocytes concerning cells with some types of cytogenetic disturbances has been demonstrated.     

Gene expression and distribution of Swi6 in partial aneuploids of the fission yeast Schizosaccharomyces pombe

Imbalances of gene expression in aneuploids, which contain an abnormal number of chromosomes, cause a variety of growth and developmental defects. Aneuploid cells of the fission yeast Schizosaccharomyces pombe are inviable, or very unstable, during mitotic growth. However, S. pombe haploid cells bearing minichromosomes derived from the chromosome 3 can grow stably as a partial aneuploid. To address biological consequences of aneuploidy, we examined the gene expression profiles of partial aneuploid strains using DNA microarray analysis. The expression of genes in disomic or trisomic cells was found to increase approximately in proportion to their copy number. We also found that some genes in the monosomic regions of partial aneuploid strains increased their expression level despite there being no change in copy number. This change in gene expression can be attributed to increased expression of the genes in the disomic or trisomic regions. However, even in an aneuploid strain that bears a minichromosome containing no protein coding genes, genes located within about 50 kb of the telomere showed similar increases in expression, indicating that these changes are not a secondary effect of the increased gene dosage. Examining the distribution of the heterochromoatin protein Swi6 using DNA microarray analysis, we found that binding of Swi6 within ~50 kb from the telomere occurred less in partial aneuploid strains compared to euploid strains. These results suggest that additional chromosomes in aneuploids could lead to imbalances in gene expression through changes in distribution of heterochromatin as well as in gene dosage.     

The origin of tertiary monosomics in the tomato

Six aneuploid tomato plants with 2n–1=23 chromosomes were observed in populations grown from the seedlings treated with thermal neutrons and from seeds treated with X-rays. Four of the aneuploids were tertiary monosomics in which, as a result of centromeric interchanges between two different chromosomes, two whole arms were missing from the complement and two arms connected at the centromere. In one aneuploid, as a result of centromeric breakage, the two short arms of a homologous pair were missing from the complement and the two long arms connected to the long arm and the short arm respectively of another chromosome in which breakage had occurred also at the centromere. In one aneuploid, the interchange has occurred in the arms, and not in the centromere. Here the aneuploid condition is due to the loss of an arm with a centromere and a short piece of the other arm.In most of the tertiary monosomics the missing arms were either the short arms of sub-metacentric chromosomes or any of the arms of metacentric chromosomes. However, in one case the long arms of two submetacentric chromosomes were lost from the complement. That in spite of such large chromosomal deletions the sporophyte can survive, may be due to the fact that the aberrant plants are mostly chimeras.This study was part of a project resulting from a contract between the Association Euratom-I.T.A.L., and the Agricultural University of Wageningen.     

A limited number of chromosomes makes a nucleus competent to respond to inducers of replication and mitosis in a plant.

Multinucleate tetraploid cells with unbalanced chromosomal distribution in aneuploid nuclei were obtained in Allium cepa L. root meristems. For this, their natural diploid cells were treated with a multipolarizing agent (1 h carbetamide) followed by an inhibitor of cytokinesis (1 h caffeine). Data from these multinucleate cells with aneuploid nuclei suggest that only four out of the thirty-two chromosomes of their autotetraploid complement possess DNA sequences making the nucleus competent to respond to inducers of replication and mitosis. Direct observation of cells where a single replicated chromosome had reached mitosis showed that this chromosome was the one bearing the nucleolar organizer. Six specific chromosomes would confer competence to the nucleus to respond to inducers of replication but not to those producing chromosome condensation. Another four different chromosomes would confer the nucleus with the ability to respond to mitotic inducers but not to replication inducers. The rest of the chromosomal complement seemed to lack any of the DNA sequences needed for these two important cycle transitions. In a nutshell, certain DNA sequences distributed in a few chromosomes of the onion complement are an intranuclear requirement to initiate replication and mitosis in these plant cells.     

Clone heterogeneity in diploid and aneuploid breast carcinomas as detected by FISH

We investigated the relationship between DNA ploidy and alterations in chromosomes 1, 8, 12, 16, 17, and 18 in 63 breast carcinoma samples by static cytofluorometry and fluorescence in situ hybridization. Thirty specimens were diploid and 33 were aneuploid. In aneuploid samples, the DNA index value ranged from 1.3 to 3.1, with a main peak near tetraploid values. Diploid clones were present in 21 of 33 aneuploid specimens. Fluorescence in situ hybridization analysis showed a heterogeneous degree of alterations in diploid specimens: one sample was normal, 16 samples had one to three chromosome alterations involving mostly chromosomes 1, 16, and 17, and 13 samples an even higher degree of alterations. The 33 aneuploid specimens showed a very high number of signals (four, five, or more). All the investigated chromosomes were affected in 23 of 33 specimens. Alterations in chromosomes 1 and 17 were detected to a similar percentage in diploid and aneuploid samples, whereas chromosome 16 monosomy was more frequent in diploid samples. Overrepresentation of chromosomes 8, 12, 16, and 18 was significantly higher in aneuploid than in diploid samples. Based on these results, we suggest that diploid and aneuploid breast carcinomas are genetically related. Chromosome 1 and 17 alterations and chromosome 16 monosomy are early changes. Allelic and chromosomal accumulations occur during progression of breast carcinoma by different mechanisms. The high clone heterogeneity found in 17 of 33 aneuploid samples could not be completely explained by endoreduplication and led to the suggestion that chromosomal instability concurs with aneuploidy development. This different evolutionary pathway might be clinically relevant because clone heterogeneity might cause metastasis development and resistance to therapy.     

Multistep Carcinogenesis: A Chain Reaction of Aneuploidizations

Carcinogenesis is a multistep process in which new, parasitic and polymorphic cancer cells evolve from a single, normal diploid cell. This normal cell is converted to a prospective cancer cell, alias "initiated", either by a carcinogen or spontaneously. The initiated cell typically does not have a new distinctive phenotype yet, but evolves spontaneously—over months to decades—to a clinical cancer. The cells of a primary cancer also evolve spontaneously towards more and more malignant phenotypes. The outstanding genotype of initiated and cancer cells is aneuploidy, an abnormal balance of chromosomes, which increases and varies in proportion with malignancy. The driving force of the spontaneous evolution of initiated and cancerous cells to ever more abnormal phenotypes is said to be their "genetic instability". However, since neither the instability of cancer phenotypes nor the characteristically slow kinetics of carcinogenesis are compatible with gene mutation, we propose here that the driving force of carcinogenesis is the inherent instability of aneuploid karyotypes. Aneuploidy renders chromosome structure and segregation error-prone, because it unbalances mitosis proteins and the many teams of enzymes that synthesize and maintain chromosomes. Thus, carcinogenesis is initiated by a random aneuploidy, which is induced either by a carcinogen or spontaneously. The resulting karyotype instability sets off a chain reaction of aneuploidizations, which generate ever more abnormal and eventually cancer-specific combinations and rearrangements of chromosomes. According to this hypothesis the many abnormal phenotypes of cancer are generated by abnormal dosages of thousands of aneuploid, but un-mutated genes.     

Formation of bipolar spindles with two centrosomes in tetraploid cells established from normal human fibroblasts

Tetraploid cells with unstable chromosomes frequently arise as an early step in tumorigenesis and lead to the formation of aneuploid cells. The mechanisms responsible for the chromosome instability of polyploid cells are not fully understood, although the supernumerary centrosomes in polyploid cells have been considered the major cause of chromosomal instability. The aim of this study was to examine the integrity of mitotic spindles and centrosomes in proliferative polyploid cells established from normal human fibroblasts. TIG-1 human fibroblasts were treated with demecolcine (DC) for 4?days to induce polyploidy, and the change in DNA content was monitored. Localization of centrosomes and mitotic spindles in polyploid mitotic cells was examined by immunohistochemistry and laser scanning cytometry. TIG-1 cells treated with DC became almost completely tetraploid at 2?weeks after treatment and grew at the same rate as untreated diploid cells. Most mitotic cells with 8C DNA content had only two centrosomes with bipolar spindles in established tetraploid cells, although they had four or more centrosomes with multipolar spindles at 3?days after DC treatment. The frequency of aneuploid cells increased as established tetraploid cells were propagated. These results indicate that tetraploid cells that form bipolar spindles with two centrosomes in mitosis can proliferate as diploid cells. These cells may serve as a useful model for studying the chromosome instability of polyploid cells.     

Multistep carcinogenesis: a chain reaction of aneuploidizations

Carcinogenesis is a multistep process in which new, parasitic and polymorphic cancer cells evolve from a single, normal diploid cell. This normal cell is converted to a prospective cancer cell, alias "initiated", either by a carcinogen or spontaneously. The initiated cell typically does not have a new distinctive phenotype yet, but evolves spontaneously--over months to decades--to a clinical cancer. The cells of a primary cancer also evolve spontaneously towards more and more malignant phenotypes. The outstanding genotype of initiated and cancer cells is aneuploidy, an abnormal balance of chromosomes, which increases and varies in proportion with malignancy. The driving force of the spontaneous evolution of initiated and cancerous cells to ever more abnormal phenotypes is said to be their "genetic instability". However, since neither the instability of cancer phenotypes nor the characteristically slow kinetics of carcinogenesis are compatible with gene mutation, we propose here that the driving force of carcinogenesis is the inherent instability of aneuploid karyotypes. Aneuploidy renders chromosome structure and segregation error-prone, because it unbalances mitosis proteins and the many teams of enzymes that synthesize and maintain chromosomes. Thus, carcinogenesis is initiated by a random aneuploidy, which is induced either by a carcinogen or spontaneously. The resulting karyotype instability sets off a chain reaction of aneuploidizations, which generate ever more abnormal and eventually cancer-specific combinations and rearrangements of chromosomes. According to this hypothesis the many abnormal phenotypes of cancer are generated by abnormal dosages of thousands of aneuploid, but un-mutated genes.     

Chromosomal changes in three cell strains of the tasmanian rat-kangaroo,Potorous tridactylis,cultured in vitro (Marsupialia)

The chromosomal changes occurring in three strains of cells from Potorous tridactylis, one derived from testis and two of kidney tissue, were followed during the in vitro life of the strains.One kidney cell strain was a slow growing one and died after 23 passages showing aneuploidy with very aberrant metaphases. The strain derived from testis showed aneuploidy after a period of growth retardation, about 50% of the aneuploid cells having 18, 19 or 20 chromosomes. In these cells the chromosomes 1, 2 and 4 were always present in triplicate and the cells always had two X-chromosomes. The second kidney strain showed aneuploidy after a period of growth retardation, cells with 22 and 23 chromosomes being the most frequent ones, but in different proportions. As the number of aneuploid cells gradually decreased, diploid cells appeared in the population. Their number also decreased and a new population of aneuploid cells arose, having 23 chromosomes, missing one chromosome nr. 5 from the tetraploid complement. Then again the cell strain returned to diploidy but as the frequency of these diploid cells decreased, the strain died out.The work was carried out, in part, under the association between Euratom and the University of Leiden, contract No. 052-64-I-BIAN, and it also received support from the Foundation for Basic Medical Research (FUNGO).     

Chromatid repulsion associated with Roberts/SC phocomelia syndrome is reduced in malignant cells and not expressed in interspecies somatic-cell hybrids.

Different cell types from a female patient with Roberts/SC phocomelia syndrome were evaluated quantitatively for the presence of repulsion of heterochromatin and satellite regions of mitotic chromosomes. Whereas EBV-transformed lymphoblasts from an established cell line revealed these phenomena at frequencies equal to those in PHA-stimulated lymphocytes and cultured skin fibroblasts, aneuploid cells from a metastatic melanoma displayed them at 50% lower frequency. Cocultivation of the patient's fibroblasts with either an immortal Chinese hamster cell line or with a human male fibroblast strain carrying a t(4;6)(p14;q21) translocation showed that the phenomenon was not corrected or induced by a diffusible factor or by cell-to-cell contact. In each experiment, only the patient's metaphase spreads revealed chromatid repulsion. In fusion hybrids between the patient's fibroblasts and an established Chinese hamster cell line, the human chromosomes behaved perfectly normally, suggesting that the gene product which is missing or mutant in Roberts/SC phocomelia syndrome is supplied by the Chinese hamster genome.     

2n or not 2n: Aneuploidy,polyploidy and chromosomal instability in primary and tumor cells

Mitotic defects leading to aneuploidy have been recognized as a hallmark of tumor cells for over 100 years. Current data indicate that ∼85% of human cancers have missegregated chromosomes to become aneuploid. Some maintain a stable aneuploid karyotype, while others consistently missegregate chromosomes over multiple divisions due to chromosomal instability (CIN). Both aneuploidy and CIN serve as markers of poor prognosis in diverse human cancers. Despite this, aneuploidy is generally incompatible with viability during development, and some aneuploid karyotypes cause a proliferative disadvantage in somatic cells. In vivo, the intentional introduction of aneuploidy can promote tumors, suppress them, or do neither. Here, we summarize current knowledge of the effects of aneuploidy and CIN on proliferation and cell death in nontransformed cells, as well as on tumor promotion, suppression, and prognosis.     

Sporadic aneuploidy in PHA-stimulated lymphocytes of trisomies 21, 18, and 13

Following the observation detected in a previous study that X chromosome monosomy in Turner's syndrome genotypes was associated with a sporadic loss and/or gain of other chromosomes, we studied here whether this instability is a consistent finding in constitutional autosomal trisomies. We used PHA-stimulated lymphocytes derived from 14 patients (10 patients with trisomy 21, 2 with trisomy 18, and 2 with trisomy 13). Fourteen healthy controls were compared. Fluorescence in situ hybridization, applied at interphase cells, was used to evaluate the level of aneuploidy for 3 randomly selected chromosomes (autosomes 8, 15, and 16) in each sample. For each tested chromosome, our results showed a significantly higher level of aneuploid cells in the samples from the patients than in those from controls, with no difference between the patient groups. The mean level of aneuploid cells (percentage) for all 3 tested autosomes was almost twice as high in the patient samples as in the control samples. The aneuploidy level was mainly due to monosomy, which was significantly higher in the samples from the patients than in those from controls for each one of the tested chromosomes, with no difference between the patient groups. The mean level of monosomic cells (percentage) for all 3 tested chromosomes was almost twice as high in the patient samples as in the control samples. Our study shows that various constitutional autosomal trisomies are associated with an increased frequency of non-chromosome specific aneuploidy and is a continuation of the previous study documenting sporadic aneuploidy in Turner's sample cells. It is possible that primary aneuploid cells destabilize their own genome resulting in variable aneuploidy of other chromosomes. It is also possible that one or several common factor(s) is/are involved in both constitutional and sporadic aneuploidy.     

Genetic control of mitosis. Mast(v40) protein--an element of checkpoints system?

The effect of the mastv40 mutation was studied using neural ganglion cells of third-instar larvae of Drosophila melanogaster. The distributions of the cells by the interphase nucleus diameter and by the distance between the sister chromosome sets in anaphase were analyzed. Three following types of defects induced by the mutation were described: (1) Monopolar mitosis or, in the case of bipolar mitosis, an abnormally short distance between the sister chromosome sets in anaphase and early telophase. We believe that these abnormalities are caused by damage of the start and (or) motor mechanisms of centrosome separation at the beginning and in the end of mitosis. (2) Lagging and bridging of chromosomes in anaphase and early telophase. These defects seem to be related to the disruption of functioning of mitotic spindle microtubules and (or) their defective attachment to the appropriate kinetochores. (3) Unlimited division of aneuploid and polyploid cells, which may be explained either by inactivation of the checkpoint system controlling the genome ploidy or by checkpoint adaptation. Taken collectively, our results and literature data suggest that the MAST protein is an element of the checkpoint system and that division of aneuploid and polyploid cells results from inactivation of the checkpoints.     

Karyotype evolution in a tumour derived plant tissue culture analysed by Giemsa C-banding

Summary A hyperdiploid aneuploid karyotype, consisting of 7 chromosomes, has been found in a tumorous suspension cell culture ofCrepis capillaris (2 n=6). Giemsa C-banding has revealed that these 7 chromosomes show consistent patterns of differential staining in all dividing cells. This stable karyotypic situation has persisted during 18 months of cytological monitoring of the culture. Comparison with the diploid C-banded complement of the root tip indicates that numerous structural rearrangements must have occurred during the formation of the aneuploid complement. A likely pathway for evolution of this karyotype involves initial tetraploidy followed by chromosome loss. Such a mechanism has previously been proposed for a plant tissue culture system (Bayliss andGould 1974) and commonly occurs in animal systems, particularly in animal tumours (Terzi andHawkins 1975). An alternative mechanism, which does not necessarily involve tetraploidy, is also proposed.