HER2 expression as a potential marker for response to therapy targeted to the EGFR.

Since human epidermal growth factor receptor 2 (HER2) is known to participate with the epidermal growth factor receptor (EGFR) in mitogenic signalling, we hypothesised that HER2 overexpression might indicate responsiveness to EGFR targeted therapies. MCF7 breast cancer cells transfected with the HER2 gene were subcloned to establish a set of genetically related cell lines expressing graded levels of HER2 by immunoblot analysis. The subcloned cell lines and parental MCF7 cells were characterised by their growth characteristics, and cell by cell patterns of EGFR, HER2 and HER3 expression as well as levels of phosphorylated mitogen-activated protein kinase (MAPK) and AKT by laser scanning cytometry (LSC). Growth inhibition assays were used to characterise response to EGFR targeted therapy, and to determine the relationship between therapeutic response and levels of tyrosine kinase expression. The levels of growth inhibition of AG1478 and of the AG1478-trastuzumab combinations were correlated with levels of HER2 expression among the different cell lines. Among EGFR, HER2 and HER3, HER2 overexpression was the best single predictive marker, but combinations of two markers provided additional predictive information.

The analysis of relapse-free survival curves: implications for evaluating intensive systemic adjuvant treatment regimens for breast cancer.

Results of adjuvant dose intensification studies in patients with localised breast cancer have raised questions regarding the clinical usefulness of this treatment strategy. Here, we develop and fit a natural history model for the time to clinical tumour recurrence as a function of the number of involved lymph nodes, and derive plausible predictions of the effects of dose intensification under various conditions. The time to tumour recurrence is assumed to depend on the residual postoperative micrometastatic burden of tumour, the fractional reduction of residual tumour burden (RTB) by treatment, and the rate of regrowth of the RTB to a clinically detectable size. It is assumed that a proportion of micrometastatic tumours are unresponsive to adjuvant chemotherapy even at maximal dose intensity. Data fitted included the San Antonio Cancer Institute (SACI) database of untreated patients, and CALGB #9082, a study comparing a highly intensive and moderately intensity adjuvant regimen in patients with 10+ positive axillary nodes. The proportion of tumours unresponsive to maximally intensive adjuvant treatment is estimated to be 48% (29-67%). The estimated log kill for intermediate-dose therapy from CALGB #9082 was 6.5 logs, compared with 9 logs or greater for high-dose therapy. The model is consistent with a modest but nonnegligible advantage of dose intensification compared with standard therapies in patients with sensitive tumours who have 10+ positive axillary nodes, and suggests that much of this clinical benefit could be achieved using intermediate levels of treatment intensification. The model further suggests that, in patients with fewer than 10 involved axillary nodes, any advantage of treatment intensification over standard therapy would be much reduced, because in patients with smaller tumour burdens of sensitive tumour, a larger proportion of cures achievable with intensified therapy could be achieved as well with standard therapy.

Distinctive patterns of Her-2/neu, c-myc, and cyclin D1 gene amplification by fluorescence in situ hybridization in primary human breast cancers.

BACKGROUND: Human solid tumors undergo clonal evolution as they progress, but evidence for specific sequences of genetic changes that occur in individual tumors and are recapitulated in other tumors is difficult to obtain. METHODS: Patterns of amplification of Her-2/neu, c-myc, and cyclin D1 were determined by fluorescence in situ hybridization (FISH) in relation to the presence of p53 dysfunction and ploidy in 60 primary human breast cancers. RESULTS: We show that there are clusters of genophenotypic abnormalities that distinguish lobular breast cancers from nonlobular tumors; that cyclin D1 amplification occurs prior to the divergence of lobular breast cancers from nonlobular cancers; that p53 dysfunction, Her-2/neu amplification, and c-myc amplification are characteristic features of nonlobular breast cancers, but not of lobular breast cancers; and that the frequencies of amplification of all three oncogenes examined increase progressively with increasing aneuploidy, but that each gene exhibits a different profile of increasing amplification in relation to tumor progression. Early amplification of c-myc appears to be an especially prominent feature of hypertetraploid/hypertetrasomic tumors. CONCLUSIONS: The data suggest that in tumors containing multiple abnormalities, these abnormalities often accumulate in the same cells within each tumor. Furthermore, the same patterns of accumulation of multiple genophenotypic abnormalities are recapitulated in different tumors.

Selective estrogen receptor modulators. An aid in unraveling the links between estrogen and breast cancer.

Breast cancer is a classic hormone-dependent malignant disease that is influenced by estrogen. However, the molecular links between estrogen and cell proliferation in healthy and malignant breast tissue are complex and as yet not well understood. The selective estrogen receptor modulators (SERMs), which are competitive inhibitors of estrogen binding at estrogen receptors alpha and beta, have become important weapons in the prevention and treatment of breast cancer. These agents also offer opportunities for the elucidation of the multiple molecular mechanisms by which estrogen affects cell proliferation. Each SERM-estrogen receptor complex has a unique structure that influences its activity in different body tissues. Unraveling the links between SERM structure and function not only may shed light on the signaling pathways that connect estrogen to cell proliferation but also may allow the design of new agents specifically targeted to affect certain events along these pathways.

Correlations among p53, Her-2/neu, and ras overexpression and aneuploidy by multiparameter flow cytometry in human breast cancer: evidence for a common phenotypic evolutionary pattern in infiltrating ductal carcinomas.

Human solid tumors develop multiple genetic abnormalities that accumulate progressively in individual cells during the course of tumor evolution. We sought to determine whether there are specific sequences of occurrence of these progressive evolutionary changes in human breast cancers by performing correlated cell-by-cell measurements of cell DNA content, p53 protein, Her-2/neu protein, and ras protein by multiparameter flow cytometry in 56 primary tumor samples obtained at surgery. In addition, p53 allelic loss and Her-2/neu gene amplification were determined by fluorescence in situ hybridization in cells from the same samples. We reasoned that if there is a specific order in which genetic changes occur, the same early changes would be found consistently in the cells with the fewest abnormalities. We reasoned further that late-developing abnormalities would not occur alone in individual cells but would almost always be found together with the early changes inherited by the same cells. By these criteria, abnormalities involving p53 generally occurred early in the course of development of invasive breast cancers, whereas ras protein overexpression was found to be a late-occurring phenomenon. Within individual tumors, cellular p53 overexpression was often observed alone in individual cells, whereas ras protein overexpression was rarely observed in the absence of p53 overexpression and/or Her-2/neu overexpression in the same cells. Furthermore, the intracellular level of each abnormally expressed protein was found to increase progressively as new abnormalities were acquired. Infiltrating ductal carcinomas exhibited characteristic phenotypic patterns in which p53 allelic loss and/or p53 protein overexpression, Her-2/neu amplification and/or overexpression, aneuploidy, and ras overexpression accumulated within individual cells. However, this pattern was not a prominent feature of lobular breast cancers. All six lobular breast cancers studied were diploid. p53 allelic loss and/or early p53 overexpression, and late ras cooverexpression in the same cells were less common in lobular breast cancers than in infiltrating ductal carcinomas. Although Her-21neu overexpression was a common finding in lobular breast cancers, Her-2/neu amplification was not observed in these tumors.

Multiparameter analysis of human epithelial tumor cell lines by laser scanning cytometry.

Laser scanning cytometry (LSC) is a relatively new slide-based technology developed for commercial use by CompuCyte (Cambridge, MA) for performing multiple fluorescence measurements on individual cells. Because techniques developed for performing four or more measurements on individual lymphoid cells based on light scatter as a triggering parameter for cell identification are not suitable for the identification of fixed epithelial tumor cells, an alternative approach is required for the analysis of such cells by LSC. Methods for sample preparation, event triggering, and the performance of multiple LSC measurements on disaggregated fixed human cells were developed using normal lymphocytes and two human breast cancer cell lines, JC-1939 and MCF-7, as test populations. Optimal conditions for individual cell identification by LSC were found to depend on several factors, including deposited cell density (cells per unit area), the dynamic range of probe fluorescence intensities, and intracellular distribution of the fluorescent probe. Sparsely deposited cells exhibited the least cell overlap and the brightest immunofluorescent staining. Major advantages of using DNA probes over a cytoplasmic immunofluorescent protein marker such as tubulin for event triggering are that the former exhibit greater fluorescence intensity within a relatively sharply demarcated nuclear region. The DNA-binding dye LDS-751 was found to be suboptimal for quantitative DNA measurements but useful as a triggering measurement that permits the performance of simultaneous fluorescein isothiocyanate-, phycoerythrin-, and indodicarbocyanine-based measurements on each cell. A major potential advantage of LSC over flow cytometry is the high yields of analyzable cells by LSC, permitting the performance of multiple panels of multicolor measurements on each tumor. In conclusion, we have developed and optimized a technique for performing multiple fluorescence measurements on fixed epithelial cells by LSC based on event triggering using the DNA-binding dye LDS 751. Although not ideal for quantitative measurements of cell DNA content, the large Stokes shift of this dye permits the performance of three or more additional fluorescence measurements on each cell.

Cell cycle models for molecular biology and molecular oncology: exploring new dimensions.

Some cell cycle models assume that cells are normally in a quiescent state until they are stimulated to enter the cell cycle and proceed through an S phase of fixed duration. Other models assume that cells normally cycle rapidly until they undergo growth retardation, proceed through an S phase of longer duration, and then undergo apoptosis or cell differentiation preferentially. These seemingly contradictory model types can be reconciled by restricting the latter type to the transition from log phase to plateau phase growth, and the former type to the recruitment of slowly proliferating cells into rapid cycle. Both proliferative states can be unified in a single cell cycle model that recognizes differences in the behavior of rapidly dividing and slowly dividing cells in the same population. Rb appears to play a major role in protecting slowly proliferating cells from apoptosis, permitting them to differentiate or persist as reserve cells that can be recruited into rapid cycle under appropriate circumstances. We examine the mechanistic basis for the recruitment phenomenon in some detail. The mitogenic signaling pathway is divided into a proximal segment, which consists of growth factor-induced membrane signaling, commonly through ras, raf, and cyclin D/cdk Rb kinase activation, and is subject to checks and balances that are designed to limit the propagation of the mitogenic signal. ras and raf compete with wild-type p53 both with respect to mitogenic signal propagation at the Rb node, and, separately, with respect to apoptosis/anti-apoptosis. The distal segment of the mitogenic signaling pathway, which consists of Rb phosphorylation, the release of E2F, the induction of c-myc, cyclins E and A, and DNA synthesis, is distinguished by a multiplicity of nested positive feedback loops; these would be expected to drive a mitogenic signal that entered the distal segment through at least one round of DNA synthesis. Using this model, we can identify two separate mechanistic strategies for neoplastic transformation. Chronic mitogenic stimulation of slowly proliferating cells would appear to be a common feature of Rb +/+ tumors. Rb -/- tumors dispense with the early segment of the mitogenic signaling pathway and its anti-apoptotic features, and maintain rapid cell cycling to compensate for high apoptotic rates.

Genetic evolutionary staging of early non-small cell lung cancer: the P53 --> HER-2/NEU --> ras sequence.

INTRODUCTION: The sequence of genetic evolutionary abnormalities that have occurred in a given lung cancer tumor before tumor sampling can be inferred from patterns of intracellular co-occurrence of these abnormalities in tumor cell subpopulations at the time of sampling. The same evolutionary sequences that are present within each lung cancer were evident in intertumor comparisons. METHODS: Correlated cell by cell measurements of cell DNA content, p53, Her-2/neu, and ras proteins were obtained by multiparameter flow cytometry on 46 surgically resected stage I-III primary non-small cell lung cancers. Early evolutionary changes were identified by the fact that they could appear alone in individual cells. Later appearing abnormalities were identified by the fact that they were accompanied by early abnormalities in the same cells. Patients were followed prospectively. Evolutionary patterns observed in individual tumors were correlated with subsequent clinical outcome of patients undergoing surgical resection. RESULTS: Three common patterns were identified: (I) a diploid DNA pathway consisting of the sequence p53 overexpression --> Her-2/neu overexpression --> ras overexpression, (II) an aneuploid DNA pathway with the same p53 --> Her-2/neu --> ras sequence, and (III) a pathway in which none of the intracellular protein measurements made here were abnormal. Fourteen tumors recurred after 11.5 months' median study time. Nine of 12 recurrences in pathways I and II occurred in patients whose tumors were far advanced along these molecular genetic pathways. CONCLUSIONS: Multiparameter cell-based genetic evolutionary studies may be a promising approach for identifying patients with stage I-III non-small cell lung cancer at high risk for recurrence.

Intracellular coexpression of epidermal growth factor receptor, Her-2/neu, and p21ras in human breast cancers: evidence for the existence of distinctive patterns of genetic evolution that are common to tumors from different patients.

Multiparameter flow cytometry studies were performed on cells from the primary tumors of 94 patients with breast cancer. Correlated cellular measurements of cell DNA content, Her-2/neu, epidermal growth factor receptor (EGFR), and p21ras levels were performed on each of 5,000 to 100,000 cells from each tumor. When criteria for positivity were matched with those in common use for immunohistochemical studies, 28 of 94 (30%) breast cancers were classified as positive for Her-2/neu overexpression. When similar criteria were applied to the EGFR measurements, 23 of 94 (24%) cases were classified as positive for EGFR overexpression. Similarly, 23 of 94 (24%) cases were classified as positive for p21ras overexpression. By conventional flow cytometric criteria for DNA ploidy, 24 cases were diploid, 28 were tetraploid, and 42 were aneuploid. When the measurements were treated as separate sets of data, the only statistically significant correlations noted were the high frequency of diploid tumors, which did not overexpress any of the three oncogenes studied (P < 0.05), and an association between Her-2/neu overexpression and aneuploidy (P < 0.03). When the data were treated as correlated intracellular measurements, 90 of the 94 tumors studied contained a population of cells in which the intracellular levels of Her-2/neu expression were directly correlated with the levels of EGFR expression in the same cells. The ratio of Her-2/neu molecules to EGFR molecules in the same cells exceeded 1 in the majority of tetraploid and aneuploid cases and was close to or less than 1 in the majority of diploid cases. In nearly all tumors, p21ras overexpression was observed only in cells that overexpressed Her-2/neu, EGFR, or both, and p21ras levels per cell were more closely correlated with levels of EGFR per cell in the same cells than with Her-2/neu levels per cell. The data are consistent with a model in which heterodimerization of Her-2/neu and EGFR in individual cells is achieved by one of several genetic evolutionary pathways, all of which commonly lead to p21ras overexpression. The two major genetic evolutionary pathways identified in this study are an aneuploid, Her-2/neu overexpression-driven pathway seen in 59 of 94 tumors, and a diploid, EGFR overexpression-driven pathway seen in 19 of 94 tumors. All tumors with Her-2/neu:EGFR ratios greater than 2 contained an infiltrating ductal carcinoma component, whereas all infiltrating pure lobular carcinomas had Her-2/ neu:EGFR ratios that were less than 2. All of the genetic evolutionary pathways identified in this study were represented among the 11 tumors from patients who experienced early tumor recurrences.

Common patterns of genetic evolution in human solid tumors.

Human solid tumors develop multiple genetic evolutionary abnormalities as they evolve. Studies that have focused primarily on early colorectal cancer have suggested that genetic instability is a prominent feature of preinvasive disease. At least two separate mechanisms for the generation of genetic instability have been identified. The first, which involves widespread microsatellite instability in near-diploid cells, affects less than one-fifth of colon cancers. The second form of genetic instability is characterized by the development of p53 gene abnormalities that result in gross aneuploidy and multiple structural chromosomal changes. p53/aneuploidy affects most colon cancers, breast cancers, and many other solid tumors. This genetic evolutionary change commonly occurs at the interface between severe dysplasia and invasive disease. Specific post-aneuploid sequences of genetic changes that are relevant to tumor progression often involve the accumulation of multiple gain-of-function abnormalities in individual cells. The co-occurrence of Her-2/neu overexpression and EGF receptor overexpression in the same aneuploid cells defines an adeno/squamous genetic evolutionary sequence that is common to ductal breast cancers, non-small cell lung cancers, and other solid tumors. Later steps in this sequence include ras and c-myc overexpression. The neuroendocrine genetic evolutionary sequence is a separate branch of the p53/aneuploidy sequence with distinctive features that include loss of Rb and raf1 overexpression. Her-2/neu overexpression is not characteristic of this sequence; c-myc amplification/overexpression is common to both p53-associated sequences. The neuroendocrine sequence is found in small cell carcinoma of the lung and in minor proportions of other solid tumors, including breast cancer. Multiparameter cell-based methods are especially well suited for elucidation in human solid tumors of the genetic evolutionary sequences that could provide a rational scientific basis for determining prognosis and for optimizing therapy in individual cancer patients.

The accumulation of multiple genetic abnormalities in individual tumor cells in human breast cancers: clinical prognostic implications.

PURPOSE: Human solid tumors undergo multiple genetic evolutionary changes as they evolve from the normal state to advanced stages of malignancy. This study characterizes the degree of advancement of primary human breast cancers in their genetic evolutionary pathways, and determines if this is of clinical significance. MATERIALS AND METHODS: Correlated cell-by-cell measurements of cell DNA content, HER-2/neu protein content per cell, and H-ras protein content per cell were obtained by means of multiparameter flow cytometry on primary tumors from 95 patients with clinically localized breast cancer. Laboratory findings were correlated with subsequent clinical course in 91 of these patients. RESULTS: Multiple genetic abnormalities were found to accumulate in individual cells in primary human breast cancers. Almost all tumors contained subsets of cells with one, two, or three abnormalities per cell in various combinations. After a median follow-up time of 32 months, 11 of 13 patients with early recurrence had primary tumors in which more than 5% of cells were hypertetraploid, overexpressed HER-2/neu protein, and overexpressed H-ras protein (triple-positive cells). The duration of disease-free survival among patients with primary tumors that contained triple-positive cells was significantly shorter than for patients whose tumors did not contain triple-positive cells. The presence of subpopulations of cells with maximums of only one abnormality per cell or only two abnormalities per cell, in any combination, was of no prognostic significance. Among patients whose nodal status was known, 12 had recurrent disease, and all had positive axillary nodes. Among 36 patients known to have negative axillary nodes, no recurrence has been reported to date. CONCLUSIONS: The number of genetic abnormalities that accumulate in individual cells in primary breast cancers reflects the degree of advancement of a tumor in its genetic evolutionary sequence, and provides useful clinical prognostic information. Because follow-up duration is still relatively short, and because disease in node-negative patients tends to recur later than in node-positive patients, it is still too early to know if three measurements per cell will be sufficient to improve prognosis in node-negative disease.

Aneuploidy in breast cancer: a fluorescence in situ hybridization study.

Although ploidy is associated with the development and progression of most breast cancers, the value of flow cytometric ploidy as a clinical prognostic factor remains controversial. The technique of fluorescence in situ hybridization (FISH) can be used not only to determine overall ploidy, but also to assess the over-representation or under-representation of specific chromosomes in interphase cells. This information may be of prognostic value. We studied 84 primary breast cancers and 20 metastatic tumors by FISH, using chromosome-specific fluorescent centromeric probes. Of these, 100 cases were also studied by DNA flow cytometry. The FISH studies were concordant with DNA flow cytometry with regard to distinguishing aneuploid from diploid tumors in 78% of cases. The FISH data suggested that aneuploidy arises by a process of chromosome complement doubling with subsequent chromosome loss. In tumors that exhibited evidence of more than one round of chromosome complement doubling, the selective accumulation of multiple copies of specific chromosomes or chromosome segments was common. Multiple copies of chromosomes centromeres 1, 3, and 17 were accumulated selectively in the cells of individual tumors more frequently than chromosomes centromeres 7, 11, and 16. Multiple copies of chromosomes centromeres 10 and 20 were selectively accumulated only rarely, if at all. Aneuploidy in breast cancer can be divided into distinct stages using fluorescence in situ hybridization techniques. The stages of aneuploidy provide potential landmarks in the genetic evolution of this disease with possible links to chromosome-specific evolutionary changes.

Origins and clinical implications of aneuploidy in early bladder cancer.

Cytogenetic and flow cytometric studies in a variety of human solid tumors have suggested that gross aneuploidy may arise by a process of abrupt chromosome complement doubling followed by gradual chromosome loss. However, this sequence has not been demonstrated directly in serial studies in individual patients in vivo. The purpose of this study was to search for evidence of chromosome complement doubling and subsequent chromosome loss in flow cytometric ploidy patterns in serial bladder washings and/or biopsies from individual patients with early bladder cancer. Fifty-two patients with noninvasive bladder cancer were followed with serial flow cytometric DNA studies for periods ranging from 5.1 to 42.7 months (median 15.1 months). Serial changes in DNA ploidy and S phase fractions were recorded and correlated with histologic and/or cytologic findings, response to treatment and clinical outcome. The data suggest a series of genetic evolutionary changes in early bladder cancer that include the initial development of peridiploid aneuploidy and repeated rounds of DNA content doubling with chromosome loss in patients with progressive disease. It is likely that gross DNA aneuploidy, and more specifically, DNA multiploidy and DNA hypertetraploidy, all arise by this mechanism. The sequence of DNA diploidy, peridiploid aneuploidy, near-tetraploidy, hypotetraploidy and hypertetraploidy is associated with a progressive increase in S phase fraction, and with increasing tumor grade; late steps in this ploidy sequence were often present in tumors that were refractory to local therapeutic measures and tumors that developed deep tumor invasion and/or distant metastases. We conclude that DNA multiploidy and hypertetraploidy are markers of advanced stages of genetic evolution in human bladder cancer.

Assessing sequential oncogene amplification in human breast cancer.

Studies of amplification and/or overexpression of c-myc, HER-2/neu, and H-ras in breast cancer have shown that each is associated with a poor prognosis. The purpose of this study was to explore the possibility that there is a preferred sequence of amplification of these oncogenes in breast cancer. The frequencies of amplification and patterns of co-amplification of c-myc, HER-2/neu, and H-ras were studied in a group of 84 breast cancers. The data suggested a preferred sequence of amplification that consisted of c-myc amplification-HER-2/neu amplification-H-ras amplification. This model was supported by loglinear analysis. In addition, the levels of amplification of JC-A, a DNA fragment newly isolated from a patient with advanced breast cancer, were studied in 61 of these cases. The data suggested that JC-A amplification occurred early. Loglinear analysis supported a model in which JC-A amplification occurred either before or after c-myc amplification but was unrelated to Her-2/neu or ras amplification.

Analytical approaches relating genetic evolutionary pathways to prognostic factors.

Human solid tumors accumulate multiple genetic abnormalities as they progress to advanced stages. Multiparameter flow cytometry measurements of individual cells within each tumor may be useful in describing the genetic pathways taken by individual tumors during the course of their genetic evolution. In this paper, we analyzed correlated cell-by-cell measurements of cell DNA content, HER-2/neu protein content, and ras protein content obtained by multiparameter flow cytometry studies of primary breast cancers from 92 patients. These laboratory findings were correlated with established clinical prognostic factors for each patient at the time of diagnosis, using a stepwise multiple analysis of variance (MANOVA). The stepwise MANOVA successively splits a group of patients into two mutually exclusive dissimilar groups, selecting the clinical prognostic factor that is most effective in doing so. Using this criterion, formation of the first three groups that were judged most dissimilar on the cytometry parameters was based on the number of positive nodes at the time of diagnosis. We show that ploidy, HER-2/neu protein content, and ras protein content, as measured by multiple parameter flow cytometry, are correlated with nodal status and other known clinical prognostic factors. The cell-by-cell multiparameter data suggest that for some individual tumors there are multiple genetic evolutionary pathways. Multiple genetic evolutionary pathways are also suggested by the MANOVA analysis. Focusing on the identification and analysis of genetic evolutionary pathways within individual tumors and across patients appears to offer a promising approach for defining the prognosis of early cancers.

Genetic and phenotypic heterogeneity of human malignancies: finding order in chaos.

The presence of cellular heterogeneity within human tumors has been recognized for many years. Current concepts regarding the clonal origin of human neoplasms, and recent advances in the study of successive genetic changes that occur during tumor evolution may now make it possible to understand in greater depth the biological and clinical implications of intra-tumor heterogeneity at both the phenotypic and genotypic levels. In order to explore these concepts further, and to better identify the potential contributions that flow and image cytometry can make to our understanding of tumor heterogeneity, a session of the 1994 ISAC Congress was dedicated to plenary presentations on human cancer cell heterogeneity. Here, we provide a brief overview of the genetic evolutionary progression of human cancers, some considerations of clinically important phenotypic and genotypic markers, and an outline that might serve as a basis for framing relevant issues that are ammenable to further study. All Nature is but Art, unknown to thee; All Chance, Direction, which thou canst not see; All Discord, Harmony not understood: All partial Evil, universal Good. (Alexander Pope, Essay on Man, end of Epistle 1).

Preferred genetic evolutionary sequences in human breast cancer: a case study.

Multiparameter flow cytometry studies were performed on the cells of an aggressive human breast cancer at the time of diagnosis and at relapse. The aneuploid cells that overexpressed large amounts of both HER-2/neu and ras survived intensive chemotherapy and were responsible for tumor relapse. At relapse, these cells were shown to overexpress simultaneously at least five oncogenes: HER-2/neu, ras, EGF receptor, p53 and c-myc. A partial reconstruction of the genetic evolutionary sequence in this tumor indicated that HER-2/neu overexpression was an early step in the sequence. Subsequent HER-2/neu overexpression, EGF receptor overexpression and p53 protein overexpression were each associated with ras overexpression. The data suggest that ploidy and oncogene overexpression cannot be used as independent clinical prognostic factors. The ability to characterize tumors according to the degree of advancement in the genetic evolutionary might serve as a basis for genetic staging for adjuvant therapy.

Sequential paraformaldehyde and methanol fixation for simultaneous flow cytometric analysis of DNA, cell surface proteins, and intracellular proteins.

A cell fixation and permeabilization procedure consisting of sequential paraformaldehyde and methanol was evaluated and found suitable for concomitant flow cytometric quantification of total cellular DNA, immunofluorescence measurements of cell surface proteins, and immunofluorescence measurements of intracellular proteins. Paraformaldehyde/methanol-fixed cells exhibited significantly greater intracellular antitubulin immunofluorescence than cells fixed with paraformaldehyde or methanol alone (p less than 0.002) and significantly greater intracellular antitubulin immunofluorescence than cells fixed with methanol followed by paraformaldehyde (p less than 0.006). With paraformaldehyde/methanol fixation, cell morphology was well preserved and forward and right angle light scatter properties were sufficiently well maintained to permit gating on these parameters. Cell surface marker staining with fluorescent anti-leukocyte antibodies was unaffected by fixation with paraformaldehyde/methanol. Paraformaldehyde effects on the intensity of DNA staining with propidium iodide were dependent on paraformaldehyde concentration and fixation temperature; these effects were least pronounced at low paraformaldehyde concentrations (0.25% or less), and at temperatures lower than 37 degrees C. Paraformaldehyde fixation may result in differences in propidium iodide staining of DNA in some diploid cells, which may produce small spurious aneuploid peaks in normal peripheral blood leukocytes. Paraformaldehyde fixation also produces an apparent increase in the DNA index of aneuploid cell populations in comparison with methanol fixation, particularly when the DNA index exceeds 1.5. Occasionally, this paraformaldehyde fixation-induced effect is useful in identifying biologically distinct near-diploid subpopulations in tumors.

Flow cytometric S fraction as a predictor of clinical outcome in cystosarcoma phyllodes.

Clinicopathologic characteristics were evaluated in 20 cases of cystosarcoma phyllodes in relation to clinical outcome. Flow cytometric DNA studies were carried out in 15 of these 20 cases. Stromal overgrowth and an infiltrating tumor border emerged as prominent histopathologic features that were associated with an unfavorable clinical outcome. Flow cytometric S fractions greater than 0.05 were associated with poor clinical outcome. There was no correlation between tumor ploidy and clinical outcome. There were no direct correlations between clinicopathologic features and flow cytometric measurements. Our data suggest that flow cytometric S fractions may be a useful predictor of clinical outcome in cystosarcoma phyllodes that can complement the traditional histologic analysis of these rare breast tumors.