Discrimination between precancerous and cancerous lesions of the uterine cervix by DNA measurements on tissue sections

Morphologically typical uterine cervical biopsies were separated into normal cervices, condylomas and cervical intraepithelial neoplasias (CIN) grades I, II and III. At least 100 nuclei per lesion were measured on 4 micron Feulgen-stained sections using a Zeiss microspectrophotometer, with a variant of the plug method used to compute the nuclear DNA content. DNA distribution histograms were then decomposed into subsets of diploid, tetraploid, octoploid and aneuploid cells. The decomposition, which assumed a log-normal model of polydiploidy distribution, led to the identification of six indices: (1) the percentage of diploid cells, (2) the percentage of tetraploid cells, (3) the percentage of octoploid cells, (4) the percentage of aneuploid cells with DNA contents less than tetraploidy, (5) the percentage of aneuploid cells with DNA contents between tetraploidy and octaploidy and (6) the percentage of aneuploid cells with DNA contents greater than octoploidy. These indices, along with the mean nuclear radius, the 5c exceeding rate and the 2c deviation index, generated a nine-dimensional space. Two methods of discriminant analysis on this space showed discriminating powers of 78.22% and 87.13%, respectively, as compared to the original diagnoses. The most discriminating variable in both analyses appeared to be the percentage of octoploid cells.     

Flow cytometric DNA content of fresh tumor specimens using keratin-antibody as second stain for two-parameter analysis.

Studies concerning flow cytometric assessed DNA content reveal problems in interpretating DNA histograms of tumor specimens. The main problems are histograms with a broad coefficient of variation in the G0/G1 fraction; a high G2M fraction and samples with a low percentage of tumor cells. Therefore, in the present study, 382 fresh tumor specimens of carcinomas were analysed routinely, double labeled with, on the one hand, propidium-iodide for assessing DNA content and, on the other, a monoclonal keratin-antibody for marking epithelial and tumor cells. Of the 311 tumor samples, using single parameter analysis 165 (54%) were classified as DNA aneuploid and 146 (46%) as DNA "euploid." By double parameter analysis, 224 (72%) samples were keratin positive and 87 (27%) keratin negative and, of the 224 keratin positive tumors, 175 (78%) were DNA aneuploid and 49 (22%) DNA euploid. The DNA histograms of single and double parameter analysis were compared and it was concluded that in 24 cases (11%) keratin labeling was necessary to recognize DNA aneuploidy. In another 23 (10%) cases, keratin labeling was helpful in assessing DNA aneuploidy. Finally when the results of the 311 samples were combined, 215 (68%) were scored as DNA aneuploid and 99 (32%) DNA euploid. Thus the overall gain in assessing DNA aneuploidy using the double labeling technique is 14%. In conclusion, it is shown that keratin labeling on fresh tumor cell suspensions of epithelial tumors is of additional value in establishing DNA content. Because single parameter DNA assessment is adequate in approximately 60% of the tested samples, the double labeling technique can be performed routinely, or after initial single parameter DNA assessment. Histograms having a broad CV and/or a high G2M are good candidates for the double labeling technique. Using this technique, DNA-content assessment becomes more reliable.     

Ploidy and morphology in osteosarcoma

In a cytometric DNA study of high-grade osteosarcoma, the relationship between DNA content and morphology was analyzed. The investigation, based on microspectrophotometry of tissue sections and flow cytometry (FCM), included both primary lesions and recurrences. FCM analysis, applied to a consecutive series of 47 primary osteosarcomas, disclosed that 2 were diploid and 45 were nondiploid, 8 of which were tetraploid. Multiple aneuploid peaks were detected in 13 tumors. Among the nondiploid tumors, there was no clear relationship between the peak DNA value(s) and the histologic subtype (osteoblastic, chondroblastic, fibroblastic) or grade (III-IV). The proliferative activity, as reflected by the percentage of S-phase cells, could be determined in 38 of the 47 tumors analyzed by FCM. The percentage was higher for aneuploid than for tetraploid lesions; however, the distribution of S-phase cells was not related to the histologic subtype or the grade of the tumors. To assess the reliability of a single sample for FCM, the DNA content of biopsy and surgical specimens was compared in 20 tumors; there was complete agreement in all cases with respect to the classification of the lesion as diploid, tetraploid or aneuploid. Analysis by FCM or microspectrophotometry of 12 local recurrences and 16 metastases and the corresponding 19 primary tumors showed that an aneuploid characteristic of the primary lesion was retained during progression of the disease. In 12 tumors analyzed by microspectrophotometry in tissue sections, comparison of chondroblastic and osteoblastic/fibroblastic areas within the same lesion consistently disclosed hyperploidy in both areas.(ABSTRACT TRUNCATED AT 250 WORDS)     

Flow cytometric determination of ploidy and proliferative activity on isolated bone marrow particles and on total bone marrow aspirate

The nuclear DNA content distribution of peripheral blood (PB) and bone marrow (BM) cells was determined by propidium iodide flow cytometry in 33 patients who underwent BM aspiration for diagnostic purposes. Two types of BM samples were taken during every aspiration procedure: whole BM aspirate, composed of BM particles contaminated by PB cells; isolated BM particles. Proliferative activity was calculated as the percentage of cells with DNA content intermediate between the diploid (2n) and the tetraploid (4n) values (2n-4n%). Ploidy was expressed as the ratio between the modal channel of the G0-G1 peak of the probe and that of an internal reference standard (DNA index, DI). The 2n-4n% was very close to zero in all PB samples. It was significantly greater in BM particles (21.2 +/- 6.6%) than in whole BM aspirate (16.6 +/- 5.5%, p less than .0005), with a close correlation (r2 = 66; p less than .0001) between the two values. Aneuploid stem lines were found in BM but not in PB. The DI of BM stem lines were similar in whole BM aspirate and BM particles, but the percentage of aneuploid cells was usually higher in BM particles. The reduced proliferative activity and the lower percent of aneuploid cells found in whole BM aspirates, with respect to BM particles, can be attributed to the contamination of BM tissue by PB, which had a very low proliferative activity and did not show aneuploidy. BM particles are therefore an easily obtained and reliable sample for routine evaluation of proliferative activity and ploidy of BM cells by DNA flow cytometry.     

Flow cytometric determination of DNA content in malignant and benign bone tumours

The nuclear DNA content of 38 malignant and 25 benign bone tumours was measured by flow cytometry. The specimens were taken either from biopsies or from surgical specimens. Seventeen of 26 primary malignant bone tumours were aneuploid, 15 had a single aneuploid DNA content, and 2 had a biclonal abnormality. Thirteen of 15 osteosarcomas were aneuploid, but only 2 of 6 chondrosarcomas showed an aneuploid DNA content. Six of 12 metastatic malignant bone tumours were also aneuploid. All 25 benign tumours had a diploid DNA content. Cell cycle analysis showed that the proportion of cells in S- and G2M-phases was higher in the malignant compared to benign tumours, indicating a higher proliferative activity. The increase was statistically significant (p less than 0.05) both in diploid and in aneuploid tumours. Among five tumours studied after chemotherapy, four displayed a marked hyperdiploid abnormality. Aneuploidy and high proliferative activity both were highly associated with malignant bone tumours, suggesting that DNA flow cytometry may be an adjunct in the assessment of malignancy of bone tumours.     

DNA image cytometry on machine-selected breast cancer cells and a comparison between flow cytometry and scanning cytophotometry

A DNA image cytometry method, implemented on the LEYTAS image processing system, has been applied to acriflavine-Feulgen-stained breast cancer cytology specimens. An essential feature of the LEYTAS image cytometry method (LCM) is the automated selection of single nuclei according to predetermined specifications. Visual interaction has been used to reject remaining artefacts like overlapping nuclei. DNA profiles obtained with LCM have been compared with DNA profiles obtained by scanning cytophotometry (SCM) or flow cytometry (FCM). The resolution of DNA profiles obtained with LCM is similar to that from SCM but lower than that from FCM. However, a high correlation is found for the DNA indices measured with LCM and FCM (r = 0.97). The LCM profiles of aneuploid tumours generally showed lower accessory diploid fractions than FCM profiles due to the automated rejection of leukocyte nuclei. Also, LCM profiles frequently showed the presence of minor subpopulations of highly aneuploid/polyploid tumour cells that could not be identified by FCM. Therefore, LCM appears to be supplementary to FCM for studying tumour cell stemline heterogeneity.     

Proliferative characteristics of primary and metastatic human solid tumors by DNA flow cytometry

The percentage of cells in S-phase (S-index) was calculated from DNA histograms of 453 primary and metastatic human solid tumors (predominantly bladder, breast, colorectal, renal, prostate, ovarian and lung carcinomas, melanomas, and sarcomas). S-indices varied widely among both primary and metastatic tumors (1-48%); there was no significant difference in S-indices between primary and metastatic tumors. The S-indices for aneuploid tumors were significantly higher than for diploid tumors. When data for all aneuploid tumors were analyzed collectively, there was no significant relationship between S-index and DNA ploidy index. However, for colorectal and ovarian carcinomas S-indices increased, and for lung carcinomas S-indices decreased with elevation in the degree of DNA-ploidy. Lung carcinomas had the highest S-indices. Comparison of flow cytometry (FCM) and cytology data indicated that for most diploid tumors S-indices reflect the proportion of S-phase cells among a mixed population of normal and tumor cells. For most aneuploid tumors, the proportion of tumor cells estimated cytologically was similar to the proportion of aneuploid cells estimated by FCM. For a small proportion of aneuploid tumors a comparison of cytology and FCM data indicated the presence of a predominant diploid tumor stemline and a minor stemline with aneuploid DNA content. There was a wide spread in the values of S-indices within tumor groups defined by degree of differentiation and stage of disease at surgery.     

Androgen receptor expression and DNA content of paraffin-embedded archival human prostate tumors

BACKGROUND: Androgen receptors (AR) are expressed in human prostate cells and immunohistochemistry has been used for qualitative analysis of AR expression in prostate tumor cells. Quantitative and multiparametric analysis of receptor expression could be of diagnostic and prognostic value in the management of patients on antiandrogen therapy. Multiparametric flow cytometric methods have been developed for analysis of hormone receptor expression and DNA content in nuclei isolated from formalin-fixed/paraffin-embedded human solid tumors. The present study was undertaken for analysis of AR expression and DNA content in archival human prostate tumors. METHODS: AR expression and DNA content were measured in nuclei isolated by enzyme digestion from thick sections cut from 51 paraffin-embedded human prostate tumors. AR expression in different subpopulations was studied by gated analysis. The relationship among AR activity, DNA content, and histopathological grade was analyzed. RESULTS: Distinct aneuploid populations were observed in 23% of tumors examined. AR activity was observed in all the specimens and the percentage of AR- positive nuclei in the 48 samples analyzed was <10% (n = 4), 11-50% (n = 39), and >51% (n = 5). Tumor subpopulations with aneuploid DNA content had higher AR expression (percent AR-positive cells and mean log fluorescence) than the diploid subpopulations. No strong correlation was seen between AR expression and histopathological grade of the tumors. CONCLUSIONS: Flow cytometric analysis of archival prostate tumor can be used for rapid determination of aneuploid DNA content and AR expression in subpopulations of nuclei isolated from formalin-fixed/paraffin-embedded prostate tumor blocks.     

Differences in the flow and absorption cytometric DNA distributions of mouse hepatocytes and tumor cells

We have determined the DNA content, the ploidy levels, and the percentages of different cell types present in small and large mouse mammary tumors as well as in young and old mouse livers by using absorption and flow cytometry. Absorption cytometry data indicated a significant increase in the proportion of transformed G0/G1 cells in the tumors as compared to that of the stromal G0/G1 cells with progressive tumor growth. This increase was not detected by flow cytometry. In both young and old mouse livers, a small number of cells of higher ploidy (8C and 16C) were detected by absorption cytometry but were not apparent in histograms obtained by flow cytometry. Furthermore, changes in the proportions of liver cells of different ploidy with age were apparent in absorption cytometry data but not in flow cytometry data. In one mouse liver experiment, a 6C cell peak appeared in the flow cytometry histogram, but a direct measurement of DNA content by absorption cytometry failed to detect cells with such a peak. We therefore believe that some caution may be warranted in the use of flow cytometry alone for evaluation of DNA distributions and of the proportions of different types of cells in complex solid tissues.     

Flow cytometry of lung carcinoma: a comparison of DNA stemline and cell cycle distribution with histology

Flow cytometry studies of the DNA distribution of 33 lung tumors were carried out. All of the carcinomas (32 cases) had aneuploid DNA modal values, ranging from 2.15c to 5.05c; in the single case of carcinoid studied, the tumor cells were diploid. DNA ploidy levels tended to be higher for epidermoid than adenocarcinoma; they were the same in lymph node metastases as in the primary tumor. Cell cycle distributions calculated from the tumor cell DNA values showed considerable variation, ranging from 9% to 58% for the S phase and from less than 1% to 29% for the G2M phase. Whether these variations have clinical significance is not known at this time.     

Modal DNA values of normal and malignant urothelial cells of the bladder in relation to nuclear size

In a study of the correlation between mean nuclear size and DNA content in urinary bladder carcinoma, the modal DNA values of cell suspensions from 125 biopsies, obtained from 86 patients with malignant or normal urinary bladder epithelium, were analyzed by flow cytometry (FCM). Light microscopic measurements of nuclear size were carried out on smears from the same material. The results were correlated to the histopathologic stage and grade. The mean nuclear volumes were significantly larger in diploid tumor cells than in cells of normal epithelium. Aneuploid tumors showed significantly larger nuclei than did diploid tumors. Although there was a significant correlation between increases in the nuclear volume and in the DNA content, there was some overlapping between various grades of malignancy: mean nuclear volumes in aneuploid grade 2 tumors did not differ from those in aneuploid grade 3 tumors. A combination of FCM and morphometry discriminated all but 16% of the tumors from the normal cases. It is concluded that FCM and morphometry are complementary and can be used for the objective characterization of urinary bladder carcinomas.     

Bone metastases: prognostic applications of cytometric DNA analysis

OBJECTIVE: To examine DNA parameters as prognostic factors for developing metastases. STUDY DESIGN: Image cytometry was used to determine DNA content of 21 tumors and 28 metastases. DNA ploidy status, 2c deviation index (2cDI) and DNA malignancy grade (DNA-MG) (based on the variation of nuclear DNA content of tumor cells around the normal DNA [2c] peak) were examined for their prognostic value. RESULTS: Twenty of 21 tumors showed aneuploid content, and 1 tumor showed diploid DNA content. Twenty-one bone metastases showed aneuploid cells. In 6 cases both euploid and aneuploid cells were detected. In 1 metastasis only euploid cells were present. DNA-MG was increased in bone metastases (mean, 2.4) as compared to the corresponding primary tumor (mean, 2.2) in most of the cases. The mean value of the 2cDI was 30.07 in primary tumors and 42.5 in metastases. Twelve bone metastases had a higher 5cEE than did the primary tumor. CONCLUSION: Diploid and aneuploid cells were able to leave a tumor and establish metastases. DNA-MG and 2cDI were increased in metastases in comparison with the primary tumor, but even tumors with lower DNA-MG had metastatic potential.     

Semiautomation of preparation of fixed paraffin-embedded tissue for DNA analysis

The usual manual preparation of single-cell suspensions from fixed paraffin-embedded tissue sections for flow cytometric (FCM) DNA ploidy analysis is a time-consuming, labor-intensive technique that requires 70 minutes to deparaffinize and rehydrate 50 microns sections as the initial step. Manual deparaffinization was compared with two semiautomated methods using an automatic slide stainer with either a 70-minute or 35-minute schedule. Samples from 6 normal tissues and 21 tumors (13 diploid and 8 aneuploid) were prepared using all three methods and analyzed by FCM. The mean cell counts in all samples were over 10(6). The DNA indices for the three samples prepared from a given tissue showed no significant differences. Using the 70-minute automation schedule, no aneuploid peaks were lost, and the ratio of G0G1 normal cells to aneuploid tumor cells was maintained. The automation of deparaffinization can thus provide a significant reduction in the labor need to produce single-cell suspensions for FCM; it can be especially helpful when handling large numbers of tumors. At the same time, the automated procedure decreases the exposure to hazardous chemicals and lowers the chance of losing tissue.     

The reliability of microspectrophotometric and flow cytometric nuclear DNA measurements in adenocarcinomas of the breast

The reliability of microspectrophotometric (MSP) and flow cytometric (FCM) nuclear DNA measurements has been studied in 50 human breast adenocarcinomas. The tumor material was obtained by means of fine-needle aspiration biopsy, and all samples except one were found to be highly representative. The results confirm earlier observations that a good correlation exists between modal value (MV) determined by MSP and DNA index (DI) determined by FCM. However, when tumors were classified into low and high malignant variants according to FCM/DI, FCM/S-phase percentages, and MSP histogram types, the concordance was less pronounced. This was found to be due mainly to the fact that in near-diploid tumors a discrepancy exists between MSP and FCM ploidy, as well as between MSP distribution pattern and the estimated percentages of cells in the S-phase region. Another source of discrepancy was observed in tumors with stemlines in the normal tetraploid region, including cells with highly scattered aneuploid DNA values. These tumors were judged by MSP as aneuploid/high malignant and by FCM as euploid/low malignant. In view of this discrepancy, we conclude that the simple determination of the stemline position by MSP/MV or FCM/DI is not sufficient for adequate cytochemical malignancy grading of breast carcinomas. We suggest that a combination of ploidy and percentage of cells scattered outside the modal peaks is a more sensitive method for optimal cytochemical malignancy grading in breast carcinomas.     

Dissociation of cellular protein and DNA content in mild and moderate dysplasia as a reflection of the degree of aneuploidy in cancer

Tumor progression was analyzed in vivo. The bronchial epithelium in five beagle dogs was weekly treated by 20-methylcholanthrene (20-MC). Bronchial cells were harvested before each application of the drug. The cytologic criteria used in the diagnostic procedure were based on a grading developed for Papanicolaou-stained preparations of human squamous bronchial epithelium. The cells were then destained and restained by Feulgen-naphthol yellow S technique. An increased variation in the protein/DNA ratio was an early event in tumorigenesis; it occurred even before aneuploid cells appeared in mild dysplasia, as compared with the control cells. A large increase in the coefficient of variation (CV) in the protein/DNA ratio in mild dysplasia vis-a-vis the control cells was positively correlated to the degree of aneuploidy occurring later in tumorigenesis. These results were compared with the findings in breast cancer cells from patients with near-diploid, aneuploid and near-tetraploid tumors. The CV in the protein/DNA ratio was significantly higher in the aneuploid tumors, indicating an increased dissociation between cell growth and DNA synthesis.     

Diagnostic value of flow cytometric DNA determination combined with fine needle aspiration biopsy in thyroid tumors

The nuclear DNA content and the numbers of cells in the S and G2M phases of the cell cycle were determined by flow cytometry (FCM) in fine needle aspirates of 187 thyroid tumors to evaluate the diagnostic value of nuclear DNA content determination in combination with aspiration cytology. DNA aneuploidy was present in 4 of 5 follicular carcinomas, 2 of 3 anaplastic carcinomas, 5 of 15 excised follicular adenomas and 2 of 20 excised adenomatous goiters; all 7 papillary carcinomas and 4 lymphomas were diploid in the aspirate. Aneuploid carcinomas had easily distinguishable S and/or G2M phases, unlike the benign aneuploid tumors. None of the histologically benign tumors or the nonexcised tumors had greater than 6% S-phase cells, and only one benign tumor had greater than 9% G2M-phase cells. In contrast, all lymphomas had greater than 10% S-phase cells and four of seven papillary carcinomas had greater than 9% G2M-phase cells. The use of FCM determination in combination with fine needle aspiration biopsy cytology improved the diagnostic potential of the latter technique.     

Apoptosis and Bcl-2 expression in relation to age, tumor characteristics and prognosis in breast cancer. South-East Sweden Breast Cancer Group.

The extent of apoptosis and the expression of Bcl-2 was investigated in tumor samples from 165 women who underwent surgery for primary breast carcinoma between 1989 and 1990 in South-East Sweden. Apoptosis was assessed by a DNA fragmentation assay for flow cytometry. Bcl-2 protein expression was analyzed with immunocytochemistry. Bcl-2 immunoreactivity correlated with estrogen receptor (ER) and progesterone receptor (PgR) positivity and was inversely correlated with p53 accumulation. Apoptosis increased with patient age and a high degree of apoptosis was negatively associated with Bcl-2 immunostaining. Apoptosis showed no significant correlation with any of the other variables studied, including prognosis. The group with Bcl-2-positive tumors tended to have a lower risk of distant recurrence than others, but the association of Bcl-2 with recurrence was different in groups divided by ER and PgR status. Whereas Bcl-2 positivity indicated a low recurrence rate among PgR-negative patients, in the PgR-positive group, those with Bcl-2-positive tumors showed a non significantly higher recurrence rate than Bcl-2-negative cases. In the PgR-positive group, Bcl-2-positive tumors also appeared more frequently to be lymph node positive and DNA aneuploid. The results suggest that hormone receptor status is of importance for the prognostic role of Bcl-2. Likewise, patient age merits consideration when apoptosis is studied in human cancer.     

Detection of residual aneuploid leukemic cells by "continuous gating".

BACKGROUND: A new method for the detection of residual aneuploid leukemic cells in bone marrow by flow cytometry is described. This method is based on the analysis of FCM derived list-mode-datasets with a new software called "Continuous Gating". The program is able to decrease the detection level of aneuploid tumor cells by analyzing groups of cells with comparable antigen density and scatter properties. METHODS: Aneuploid acute lymphocytic leukemia cells with a known CD34 expression were diluted with diploid bone marrow cells to a concentration of 10, 1, 0.1, 0.05, and 0.01%. Each sample was measured in a FACScan flow cytometer, after staining with CD34 Moab and propidium iodide. Listmode-data were analyzed with the new "Windows"-based "Continuous Gating" software. A gate was set in the DNA parameter, defining the channels in which the aneuploid G0/G1-peak of possible residual tumor-cells should be found. Ten thousand overlapping gates of size 200 x 200 channels (out of 1,023 x 1,023 channels) were set automatically by the program into the side-scatter (SSC)/CD34 dot-plot, calculating the percentage of aneuploid G0/G1-phase cells for every specific gate. RESULTS: The results are plotted in a contour-plot. In dot-plot gates with less than 20 cells, the calculation of the percentage of aneuploid cells was declared invalid and the area in the contour-plot was marked. Detection of residual aneuploid cells, based on a defined expression of CD34 and granularity (SSC), was possible down to a contamination of 0.1%. CONCLUSIONS: The new "Continuous Gating" software can be used for the automated detection of aneuploid leukemic cells, if the density of a certain surface-marker is slightly different from normal cells.     

Nuclear protein content and Ki-67 immunoreactivity in nonneoplastic and neoplastic thyroid cells.

The nuclear DNA content in thyroid tumor cells has been shown to be closely related to the malignant potential of the neoplasm. Besides DNA, nuclear protein (NP) constitutes the major mass of the nucleus. The NP content may vary significantly in relation to the proliferative stage in growing as compared to growth-arrested cells. The increase in NP content associated with the transition from G0 to G1 occurs before the onset of DNA synthesis and may be used to assess growth activity. The nuclear DNA and NP contents were analyzed in 90 nonneoplastic lesions and 75 benign and 62 malignant thyroid tumors. All nonneoplastic specimens were euploid, and 1 of 90 was growth activated. In the group of benign tumors, 59 were euploid, and 16 were aneuploid. Among these there were 5 (9%) of 59 and 6 (38%) of 16 growth-activated specimens, respectively. In the group of malignant tumors 57 of 62 were classified as euploid, and in this group 12 (21%) showed growth activity according to the NP content. Five of 62 were aneuploid, and 3 (60%) of these 5 tumors were growth activated. Evaluation of the growth activity by means of monoclonal antibody Ki-67 was performed on a subgroup of 32 thyroid specimens, both nonneoplastic and neoplastic lesions. Ki-67 immunoreactivity was observed in 0-1.1% cells of 6 nonneoplastic lesions, in 0-3.1% cells of 14 benign cells and in 0.2-3.9% cells of 12 malignant thyroid tumors. Growth activity, as reflected by the NP/DNA ratio and Ki-67 immunoreactivity, appears to be low both in nonneoplastic thyroid lesions and thyroid tumors.     

Non-random distribution of abnormal mitoses in heteroploid cell lines.

We have performed absorption-cytometric DNA measurements of the DNA contents of the G0/G1, G2, metaphase, and telophase cells of the heteroploid MCa-11 and HL-60 lines, as well as the WCHE-5 line which has a narrowly restricted number of chromosomes. We found that morphologically unbalanced mitoses occurred much more frequently in telophase-cell pairs of the heteroploid MCa-11 and HL-60 lines than in those of the chromosomally stable WCHE-5 line. Furthermore, the morphologically unbalanced mitoses represented unequal segregation of DNA into each of the daughter telophase nuclei. Such mitotic segregation errors (MSE) occurred almost exclusively in telophase cells with DNA contents which were above, or below, the DNA content of the modal telophase population. The net effect of these non-random, unblanced divisions of heteroploid cells with non-modal DNA contents is to produce one daughter cell with a DNA content that tends to return to the modal DNA content peak.