Human Breast Cancer Cell Lines Co-Express Neuronal,Epithelial, and Melanocytic Differentiation Markers In Vitro and In Vivo

Differentiation programs are aberrant in cancer cells allowing them to express differentiation markers in addition to their tissue of origin. In the present study, we demonstrate the multi-lineage differentiation potential of breast cancer cell lines to express multiple neuronal/glial lineage-specific markers as well as mammary epithelial and melanocytic-specific markers. Multilineage expression was detected in luminal (MCF-7 and SKBR3) and basal (MDA-MB-231) types of human breast cancer cell lines. We also observed comparable co-expression of these three cell lineage markers in MDA-MB-435 cells in vitro, in MDA-MB-435 primary tumors derived from parental and single cell clones and in lung metastases in vivo. Furthermore, ectoderm multi-lineage transdifferentiation was also found in human melanoma (Ul-MeL) and glioblastoma cell lines (U87 and D54). These observations indicate that aberrant multi-lineage transdifferentiation or lineage infidelity may be a wide spread phenomenon in cancer.     

Lineage infidelity in chronic myeloid leukemia. Demonstration and significance of hybridoid leukocytes

Blood smears from 13 cases of chronic myeloid leukemia (CML) were examined for bigranulated (basophil/eosinophil) cells. The cells were stained with May-Grünwald-Giemsa, toluidine blue, Biebrich scarlet, Adams' reaction, and were reacted for KCN-resistant peroxidase in two cases. A sequential stain (toluidine blue/Biebrich scarlet/Adams' reaction) was applied to 50 cells in each case. Hybridoid cells occurred in all cases with varying frequency. Double granulation was not only found in immature, non-segmented cells but often in mature segmented cells. The chimeric cells were difficult to detect with May-Grünwald-Giemsa. Biebrich scarlet and Adams' reaction being superior in this respect to Biebrich scarlet. Some granules that were positive by Adams' reaction did not stain with Biebrich scarlet. This is in sharp contrast to the normal and is, therefore, interpreted as a granule atypicality. Since under normal circumstances, eosinophilic and basophilic granules can be viewed as mutually exclusive markers of the respective granulocytic lineages, the simultaneous occurrence in CML cells of both markers demonstrates lineage infidelity. Until now lineage infidelity has been reported only in immature cells. However, our results show that lineage infidelity also occurs in mature segmented cells. This indicates that the progenitors of these chimeric granulocytes follow false genetic programs producing cells with profound irreversible neoplastic aberrations.     

Clonal variation in gene methylation: c-H-ras and alpha-hCG regions vary independently in human fibroblast lineages

The stability of DNA methylation has been followed in clonal lineages of human diploid fibroblasts, for the gene regions encoding the c-H-ras proto-oncogene and the alpha subunit of human chorionic gonadotropin (alpha-hCG). Although methylation losses predominated, both de novo gains and losses of cytosine methylation were observed in subclones and sub-subclones, at frequencies which differed between individual clonal lineages, and between the 2 gene regions compared. Methylation of these loci varied independently among clones; e.g., a lineage which showed frequent methylation loss in the c-H-ras gene region remained highly methylated for alpha-hCG, and vice versa. Thus, the fidelity with which DNA methylation is inherited in specific endogenous gene regions must be governed by a clone-specific property affecting local chromatin structure, but apparently not by gene expression per se. Late in the replicative life-span of diploid fibroblasts, as cell replication slowed, restriction patterns for methylation-sensitive enzymes became simpler and more discrete, while those for other enzymes did not change. This is interpreted as a consequence of 'clonal succession', in which the fastest-replicating or longest-lived clones/subclones eventually predominate in a cell population; it could also reflect a decreased rate or a non-random selection of methylation changes in late-passage cells.     

Loss of viral gene expression and retention of tumorigenicity by Abelson lymphoma cells.

Lymphomas induced by the Abelson murine leukemia virus (A-MuLV) were examined for the expression of biochemical and biological markers associated with A-MuLV transformation before and after in vivo growth in genetically distinguishable host mice. Although all tumors and clonal lines derived from them initially expressed the A-MuLV-encoded gag fusion protein p160, they ceased synthesis of this molecule after several weeks of growth in vivo as ascites tumors. Transplanted clonal lines continued to express the alloantigenic marker H-2b and the isoenzyme marker Gpi-1b of the donor tumor cells, indicating that the cells were of donor and not host origin. Examination of cellular DNA obtained from p160-positive and derivative p160-negative lines indicated that p160-negative clones had lost A-MuLV-specific proviral sequences as detected by hybridization with several probes. Although the clonal lines no longer expressed p160, they retained their malignant phenotype and continued to express the Abelson antigen, a cell surface marker associated with A-MuLV lymphomagenesis. Continued expression of the A-MuLV genome was not required for maintenance of oncogenic potential under these conditions of in vivo tumor growth.     

Continuously growing bipotential and monopotential myogenic, adipogenic, and chondrogenic subclones isolated from the multipotential RCJ 3.1 clonal cell line

The clonal multipotential RCJ 3.1 cell line, which gives rise to myotubes, adipocytes, chondrocytes, and osteoblasts, contains different progenitor subpopulations. By limiting dilution analysis, of 296 single colonies identified, approximately 20% contained a single recognizable cell type, approximately 10% contained two cell types, and approximately 1% contained three cell types. We recloned RCJ 3.1 and isolated continuously growing subclones, including four novel bipotential (adipocytes/chondrocytes; adipocytes/myotubes and chondrocytes/myotubes) cell populations, whose phenotypes bred true. In the bipotential subclones, single colony analyses confirmed the presence of single cells which could both self-renew the bipotential progenitors and give rise to their respective committed monopotential lineages. Eight subclones were restricted to a single cell lineage and were considered monopotential; one of these is a novel cell line differentiating into cartilage. Thus, we have isolated unique monopotential and bipotential progenitor cell lines which provide a valuable model for studying the mechanisms leading to lineage restriction in mesenchymal populations.     

Analyzing expression of perforin, Runx3, and Thpok genes during positive selection reveals activation of CD8-differentiation programs by MHC II-signaled thymocytes

Intrathymic positive selection matches CD4-CD8 lineage differentiation to MHC specificity. However, it is unclear whether MHC signals induce lineage choice or simply select thymocytes of the appropriate lineage. To investigate this issue, we assessed thymocytes undergoing positive selection for expression of the CD8 lineage markers perforin and Runx3. Using both population-based and single-cell RT-PCR analyses, we found large subsets of MHC class II (MHC-II)-signaled thymocytes expressing these genes within the CD4+ 8+ and CD4+ 8(int), but not the CD4+ 8- populations of signaling competent mice. This indicates that MHC-II signals normally fail to impose CD4 differentiation and further implies that the number of mature CD8 single-positive (SP) thymocytes greatly underestimates CD8 lineage choice. We next examined whether MHC-II-restricted CD4+ 8- thymocytes remain competent to initiate CD8 lineage gene expression. In mice in which expression of the tyrosine kinase Zap70 and thereby TCR signaling were impaired selectively in SP thymocytes, MHC-II-signaled CD4+ 8- thymocytes expressed perforin and Runx3 and failed to up-regulate the CD4 marker Thpok. This indicated that impairing TCR signals at the CD4 SP stage switched gene expression patterns from CD4- to CD8-lineage specific. We conclude from these findings that MHC-II-signaled thymocytes remain competent to initiate CD8-specific gene expression even after CD8 down-regulation and that CD4 lineage differentiation is not fixed before the CD4 SP stage.     

The MEC1 and MEC2 Lines Represent Two CLL Subclones in Different Stages of Progression towards Prolymphocytic Leukemia

The EBV carrying lines MEC1 and MEC2 were established earlier from explants of blood derived cells of a chronic lymphocytic leukemia (CLL) patient at different stages of progression to prolymphocytoid transformation (PLL). This pair of lines is unique in several respects. Their common clonal origin was proven by the rearrangement of the immunoglobulin genes. The cells were driven to proliferation in vitro by the same indigenous EBV strain. They are phenotypically different and represent subsequent subclones emerging in the CLL population. Furthermore they reflect the clinical progression of the disease. We emphasize that the support for the expression of the EBV encoded growth program is an important differentiation marker of the CLL cells of origin that was shared by the two subclones. It can be surmised that proliferation of EBV carrying cells in vitro, but not in vivo, reflects the efficient surveillance that functions even in the severe leukemic condition. The MEC1 line arose before the aggressive clinical stage from an EBV carrying cell within the subclone that was in the early prolymphocytic transformation stage while the MEC2 line originated one year later, from the subsequent subclone with overt PLL characteristics. At this time the disease was disseminated and the blood lymphocyte count was considerably elevated. The EBV induced proliferation of the MEC cells belonging to the subclones with markers of PLL agrees with earlier reports in which cells of PLL disease were infected in vitro and immortalized to LCL. They prove also that the expression of EBV encoded set of proteins can be determined at the event of infection. This pair of lines is particularly important as they provide in vitro cells that represent the subclonal evolution of the CLL disease. Furthermore, the phenotype of the MEC1 cells shares several characteristics of ex vivo CLL cells.     

Characterization of human embryonic stem cell lines by the International Stem Cell Initiative

The International Stem Cell Initiative characterized 59 human embryonic stem cell lines from 17 laboratories worldwide. Despite diverse genotypes and different techniques used for derivation and maintenance, all lines exhibited similar expression patterns for several markers of human embryonic stem cells. They expressed the glycolipid antigens SSEA3 and SSEA4, the keratan sulfate antigens TRA-1-60, TRA-1-81, GCTM2 and GCT343, and the protein antigens CD9, Thy1 (also known as CD90), tissue-nonspecific alkaline phosphatase and class 1 HLA, as well as the strongly developmentally regulated genes NANOG, POU5F1 (formerly known as OCT4), TDGF1, DNMT3B, GABRB3 and GDF3. Nevertheless, the lines were not identical: differences in expression of several lineage markers were evident, and several imprinted genes showed generally similar allele-specific expression patterns, but some gene-dependent variation was observed. Also, some female lines expressed readily detectable levels of XIST whereas others did not. No significant contamination of the lines with mycoplasma, bacteria or cytopathic viruses was detected.     

Telomere Length Dynamics in Telomerase-Positive Immortal Human Cell Populations

It has been proposed that the progressive shortening of telomeres in somatic cells eventually results in senescence. Previous experiments have demonstrated that many immortal cell lines have acquired telomerase activity leading to stabilization of telomere length. Telomere dynamics and telomerase activity were examined in the telomerase-positive immortal cell lines HeLa and 293 and subclones derived from them. A mass culture of HeLa cells had a stable mean telomere length over 60 population doublings (PD)in vitro.Subclones of this culture, however, had a range of mean telomere lengths indicating that telomeric heterogeneity exists within a population with a stable mean telomere length. Some of the subclones lacked detectable telomerase activity soon after isolation but regained it by PD 18, suggesting that at least some of the variation in telomere length can be attributed to variations in telomerase activity levels. 293 subclones also varied in telomere length and telomerase activity. Some telomerase-positive 293 subclones contained long telomeres that gradually shortened, demonstrating that factors other than telomerase also act to modulate telomere length. Fluctuations in telomere length in telomerase-positive immortalized cells may contribute to chromosomal instability and clonal evolution.     

Genetic heterogeneity of stably transfected cell lines revealed by expression profiling with oligonucleotide microarrays

Large-scale gene expression measurements with oligonucleotide microarrays have contributed tremendously to biological research. However, to distinguish between relevant expression changes and falsely identified positives, the source and magnitude of errors must be understood. Here, we report a source of biological variability in microarray experiments with stably transfected cell lines. Mouse embryonic fibroblast (MEF/3T3) and rat schwannoma (RT4) cell lines were generated to provide regulatable schwannomin expression. The expression levels of 29 samples from five different mouse embryonic fibroblast clonal cell lines and 18 samples from 3 RT4 cell lines were monitored with oligonucleotide microarrays. Using hierarchical clustering, we determined that the changes in gene expression induced by schwannomin overexpression were subtle when compared with those detected as a consequence of clonal selection during generation of the cell lines. The hierarchical clustering implies that significant alterations of gene expression were introduced during the transfection and selection processes. A total of 28 genes were identified by Kruskal-Wallis rank test that showed significant variation between clonal lines. Most of them were related to cytoskeletal function and signaling pathways. Based on these analyses, we recommend that replications of experiments with several selected cell lines are necessary to assess biological effects of induced gene expression.     

Generation of diversity in the innate immune system: macrophage heterogeneity arises from gene-autonomous transcriptional probability of individual inducible genes.

Microbial products such as LPS stimulate macrophages to produce a wide diversity of inducible gene products needed for immediate host defense and priming of an appropriate acquired immune response. In this study, we have examined LPS-inducible gene expression in subclones of a mouse macrophage cell line, RAW264, using cDNA microarrays. Even archetypal target genes such as TNF-alpha were not induced in all subclones, and there was no absolute correlation between expression of pairs of genes. Nevertheless, the array analysis revealed clusters of genes that were more likely to be coexpressed. RAW264 cells stably transfected with luciferase reporter genes driven by LPS-responsive promoters revealed the same kind of clonal heterogeneity. The results indicate that each LPS-inducible gene has its own inherent probability of activation in response to LPS.     

Increased epidermal growth factor receptor in multidrug-resistant human neuroblastoma cells

Multidrug-resistant human neuroblastoma cell lines obtained by selection with vincristine or actinomycin D from two independent clonal lines, SH-SY5Y and MC-IXC, have 3- to 30-fold more cell surface epidermal growth factor (EGF) receptors than the drug-sensitive parental cells as indicated by EGF binding assays and immunoprecipitation, affinity-labeling, and phosphorylation studies. Reversion to drug sensitivity in one line was accompanied by a return to the parental level of EGF receptor. SH-EP cells, a clone derived from the same neuroblastoma cell line as SH-SY5Y but which displays melanocyte rather than neuronal lineage markers, also express significantly more EGF receptor than SH-SY5Y cells. By nucleic acid hybridization analysis with a molecularly cloned probe, increased receptor level in multidrug-resistant cells was shown to be the result of higher levels of EGF receptor mRNA in drug-resistant than in drug-sensitive cells. The increased steady state amount of specific RNA did not result from amplification of receptor-encoding genes. A small difference was observed in the electrophoretic mobility under denaturing conditions of EGF receptor immunoprecipitated from drug-resistant and drug-sensitive cells. Quantitative and qualitative modulation of the EGF receptor might reflect alterations in the transformation and/or differentiation phenotype of the resistant cells or might result from unknown selective pressures associated with the development of multidrug resistance.     

Differences between human and mouse embryonic stem cells

We compared gene expression profiles of mouse and human ES cells by immunocytochemistry, RT-PCR, and membrane-based focused cDNA array analysis. Several markers that in concert could distinguish undifferentiated ES cells from their differentiated progeny were identified. These included known markers such as SSEA antigens, OCT3/4, SOX-2, REX-1 and TERT, as well as additional markers such as UTF-1, TRF1, TRF2, connexin43, and connexin45, FGFR-4, ABCG-2, and Glut-1. A set of negative markers that confirm the absence of differentiation was also developed. These include genes characteristic of trophoectoderm, markers of germ layers, and of more specialized progenitor cells. While the expression of many of the markers was similar in mouse and human cells, significant differences were found in the expression of vimentin, beta-III tubulin, alpha-fetoprotein, eomesodermin, HEB, ARNT, and FoxD3 as well as in the expression of the LIF receptor complex LIFR/IL6ST (gp130). Profound differences in cell cycle regulation, control of apoptosis, and cytokine expression were uncovered using focused microarrays. The profile of gene expression observed in H1 cells was similar to that of two other human ES cell lines tested (line I-6 and clonal line-H9.2) and to feeder-free subclones of H1, H7, and H9, indicating that the observed differences between human and mouse ES cells were species-specific rather than arising from differences in culture conditions.     

Mesodermal cell lineage determination and proto-oncogene expression

Previously, we have established a rat embryo fibroblastic cell line that is characterized as immortal, nontumorigenic and retains a diploid karyotype. We report here that this cell line will spontaneously differentiate along mesodermal cell lineages to form myotubes and adipocytes. We have isolated and characterized lineage-determined (nondifferentiated) preadipocytes and myoblasts. Using these cell lines we have investigated the expression of proto-oncogenes concomitant with lineage-specific determination. No major changes in proto-oncogene RNA levels were observed that correlated with lineage determination. These results would suggest that none of the 15 proto-oncogenes used in these experiments are involved in mesodermal lineage determination; but this does not rule out the possibility that other proto-oncogenes not tested or currently unknown may be involved. However, these differentiating subclones and nondifferentiating fibroblasts that exhibit a normal karyotype will be an excellent model-system to investigate the molecular basis of cell lineage determination.     

History of immunology. Development of the concept of immunologic specificity, I

The induction of differentiation in human malignant T-lymphoblastic cell lines MOLT-3 and Jurkat by the tumor promoter, 12-O-tetradecanoylphorbol 13-acetate (TPA) was examined using the monoclonal antibodies OKT3, OKT4, OKT6, and OKT8 which are known to react with human T-cell differentiation antigens. It was found that in the presence of nanomolar concentrations of TPA the proportion of OKT3⁺ (mature T-cell marker) cells increased while the proportion of OKT4⁺, OKT6⁺, and OKT8⁺ (relatively immature T-cell markers) cells decreased. These changes in the distribution of the OKT antigens in MOLT-3 cells were found to be more prominent with MOLT-3 cells than when the Jurkat cells were used. In studies using a double labeling approach it was found that although the OKT3⁺ and E-rosette-positive (E⁺) cells appeared to belong to the same subpopulations of MOLT-3 cells, the OKT3 antigen was probably not related to the receptor for sheep erythrocytes because adsorption of the OKT3 antibody did not block E-rosette formation. Studies using the DNA synthesis inhibitor, arabinosylcytidine (ara-C) also indicate that DNA synthesis was not required for the induction of more mature T-cell antigens in the malignant T-cell lines by TPA. These studies, taken together with our earlier reports, support the conclusion that namomolar concentrations of TPA can induce differentiation in these malignant T-cell lines. Furthermore we have shown that the T-cell hybridoma antibodies are useful markers to detect differentiation changes in human T cells.     

Clonal variability within dihydrofolate reductase-mediated gene amplified Chinese hamster ovary cells: stability in the absence of selective pressure

Recombinant Chinese hamster ovary (rCHO) cells expressing a high level of chimeric antibody were obtained by cotransfection of heavy- and light-chain cDNA expression vectors into dihydrofolate reductase-deficient CHO cells and subsequent gene amplification in medium containing stepwise increments in methotrexate (MTX) level up to 1.0 microM. To determine the clonal variability within the amplified cell population in regard to antibody production stability, 20 subclones were randomly isolated from the amplified cell population at 1.0 microM MTX (CS13-1.0 cells). Clonal analysis showed that CS13-1.0 cells were heterogeneous with regard to specific growth rate (mu) and specific antibody productivity (qAb), although they were derived from a single clone. The mu and qAb of 20 subclones were in the range of 0.51 to 0.72 day-1 and 10.9 to 19.1 microgram/10(6) cells/day, respectively. During 8 weeks of cultivation in the absence of selective pressure, the mu of most subclones did not change significantly. On the other hand, their qAb decreased significantly. Furthermore, the relative decrease in qAb varied among subclones, ranging from 30% to 80%. Southern and Northern blot analyses showed that this decreased qAb resulted mainly from the loss of amplified immunoglobulin (Ig) gene copies and their respective cytoplasmic mRNAs. For the sake of screening convenience, an attempted was made to correlate the initial properties of subclones (such as mu, qAb, and Ig gene copies) with their antibody production stability during long-term culture. Among these initial properties examined, only qAb of subclones could help to predict their stability to some extent. The subclones with high qAb were relatively stable with regard to antibody production during long-term culture in the absence of selective pressure (P < 0. 005, ANOVA). Taken together, the clonal heterogeneity in an amplified CHO cell population necessitates clonal analysis for screening stable clones with high qAb.