Plating efficiency as a function of time postirradiation: evidence for the delayed expression of lethal mutations

The plating efficiency (PE) of a gamma-irradiated (7 Gy) human cell hybrid line (HeLa X skin fibroblast, designated as CGL1) has been measured as a function of time postirradiation and compared to that of unirradiated cells at similar cell densities and under the same growth conditions. The results indicate that following irradiation, the PE of the irradiated cells initially increases but never returns to that of unirradiated cells during the experimental period that we have examined. Furthermore, after a period of 9 to 10 days (equivalent to at least 10 cell doublings) postirradiation and plating, the PE of the irradiated cells begins to decrease and continues to do so over the next 5 days. A decrease does not occur in unirradiated cells until much later (i.e., Day 15) corresponding to at least 5 additional cell doublings. The data are discussed in terms of a delayed expression of lethal mutations. The possible impact of these observations on the estimation of radiation-induced transformation frequencies is also considered.     

Tissue Inhibitor of Metalloproteinase 1 Expression Associated with Gene Demethylation Confers Anoikis Resistance in Early Phases of Melanocyte Malignant Transformation

Although anoikis resistance has been considered a hallmark of malignant phenotype, the causal relation between neoplastic transformation and anchorage-independent growth remains undefined. We developed an experimental model of murine melanocyte malignant transformation, where a melanocyte lineage (melan-a) was submitted to sequential cycles of anchorage blockade, resulting in progressive morphologic alterations, and malignant transformation. Throughout this process, cells corresponding to premalignant melanocytes and melanoma cell lines were established and show progressive anoikis resistance and increased expression of Timp1. In melan-a melanocytes, Timp1 expression is suppressed by DNA methylation as indicated by its reexpression after 5-aza-2′-deoxycytidine treatment. Methylation-sensitive single-nucleotide primer extension analysis showed increased demethylation in Timp1 in parallel with its expression along malignant transformation. Interestingly, TIMP1 expression has already been related with negative prognosis in some human cancers. Although described as a MMP inhibitor, this protein has been associated with apoptosis resistance in different cell types. Melan-a cells overexpressing Timp1 showed increased survival in suspension but were unable to form tumors in vivo, whereas Timp1-overexpressing melanoma cells showed reduced latency time for tumor appearance and increased metastatic potential. Here, we demonstrated for the first time an increment in Timp1 expression since the early phases of melanocyte malignant transformation, associated to a progressive gene demethylation, which confers anoikis resistance. In this way, Timp1 might be considered as a valued marker for melanocyte malignant transformation.     

Haymaker gene expression in malignant and normal gynecologic tissues.

We previously reported that cell lines established from human carcinomas and leukemias/lymphomas expressed high levels of an intracellular membrane-bound protein, Haymaker, whereas cell lines derived from non-malignant connective tissue cells and lymphoid cells expressed low levels of this gene product. To determine whether these findings reflect neoplastic transformation or, alternatively, tissue specificity, we examined by immunohistochemical and molecular methods the expression of Haymaker in gynecologic organs with and without tumor. A highly specific, affinity-purified rabbit polyclonal antibody against a 25-mer Haymaker peptide was used for immunohistochemical staining and morphometric analysis of 85 tissue specimens. Immunohistochemical studies demonstrate, for the first time, that Haymaker protein is highly expressed in epithelial cells of the endometrium of the normal uterus and to a somewhat lesser extent in the mucosa of the normal vagina and cervix, but is poorly expressed or absent in cells of the connective tissue and smooth muscle strata of these organs (p < 0.005). Significant differences in Haymaker expression, as assessed by immunohistochemistry, between malignant and normal gynecologic tissues were not observed (p = 0.27). The expression of Haymaker protein does not appear, therefore, to be a marker of malignant transformation of the epithelium of gynecologic organs but rather distinguishes both normal and malignant epithelial cells from normal connective tissue and smooth muscle cells.     

Immunoperoxidase staining of cervicovaginal smears after radiotherapy.

Cervicovaginal smears from 2 women with postirradiation dysplasia, 4 women with postirradiation squamous cell carcinoma of the cervix, 30 women with irradiation atypia and 5 healthy, nonirradiated women were stained immunohistochemically with six keratin antibodies. For four of the antibodies--CK19 (BA17), EMA, PKK-1 and CAM 5.2--squamous cells showing irradiation atypia, postirradiation dysplasia or postirradiation squamous cell carcinoma were more likely to stain positively than were nonirradiated squamous cells. For three of the antibodies in which multiple squamous cells stained positively, the proportion of squamous cells showing postirradiation dysplasia or postirradiation squamous cell carcinoma staining strongly was equal to or greater than the corresponding overall proportion for squamous cells showing irradiation atypia. This was statistically significant with only one antibody, PKK-1. No statistically significant differences were seen in staining of irradiated and nonirradiated squamous cells by MAK-6 and AE1:AE3. The data show that some keratin antigens are more often expressed in the irradiated groups and that there may be differences in the degree of antigen expression between squamous cells showing postirradiation dysplasia or postirradiation squamous cell carcinoma and squamous cells showing irradiation atypia.     

Human colon tissue in organ culture: preservation of normal and neoplastic characteristics

Normal and neoplastic human colon tissue obtained at surgery was used to establish conditions for organ culture. Optimal conditions included an atmosphere of 5% CO₂ and 95% O₂; tissue partially submerged with mucosa at the gas interface; and serum-free medium with 1.5 mM Ca²⁺ and a number of growth supplements. Histological, histochemical, and immunohistochemical features that distinguish normal and neoplastic tissue were preserved over a 2-d period. With normal tissue, this included the presence of elongated crypts with small, densely packed cells at the crypt base and mucin-containing goblet cells in the upper portion. Ki67 staining, for proliferating cells, was confined to the lower third of the crypt, while expression of extracellular calcium-sensing receptor was seen in the upper third and surface epithelium. E-cadherin and β-catenin were expressed throughout the epithelium and confined to the cell surface. In tumor tissue, the same disorganized, abnormal glandular structures seen at time zero were present after 2 d. The majority of cells in these structures were mucin-poor, but occasional goblet cells were seen and mucin staining was present. Ki67 staining was seen throughout the abnormal epithelium and calcium-sensing receptor expression was weak and variable. E-cadherin was seen at the cell surface (similar to normal tissue), but in some places, there was diffuse cytoplasmic staining. Finally, intense cytoplasmic and nuclear β-catenin staining was observed in cultured neoplastic tissue.     

Proteome analysis of NIH3T3 cells transformed by activated Galpha12: regulation of leukemia-associated protein SET

Galpha(12), the alpha-subunit of the G12 family of heterotrimeric G proteins is involved in the regulation of cell proliferation and neoplastic transformation. GTPase-deficient, constitutively activated mutant of Galpha(12) (Galpha(12)Q229L or Galpha(12)QL) has been previously shown to induce oncogenic transformation of NIH3T3 cells promoting serum- and anchorage-independent growth. Reduced growth-factor dependent, autonomous cell growth forms a critical defining point at which a normal cell turns into an oncogenic one. To identify the underlying mechanism involved in such growth-factor/serum independent growth of Galpha(12)QL-transformed NIH3T3, we carried out a two-dimensional differential proteome analysis of Galpha(12)QL-transformed NIH3T3 cells and cells expressing vector control. This analysis revealed a total of 22 protein-spots whose expression was altered by more than 3-folds. Two of these spots were identified by MALDI-MS analysis as proliferating cell nuclear antigen (PCNA) and myeloid-leukemia-associated SET protein. The increased expressions of these proteins in Galpha(12)QL cells were validated by immunoblot analysis. Furthermore, transient transfection studies with NIH3T3 cells indicated that the expression of activated Galpha(12) readily increased the expression of SET protein by 24 h. As SET has been previously reported to be an inhibitor of phosphatase PP2A, the nuclear phosphatase activity was monitored in cells expressing activated Galpha(12). Our results indicate that the nuclear phosphatase activity is inhibited by greater than 50% in Galpha(12)QL cells compared to vector control cells. Thus, our results from differential proteome analysis presented here report for the first time a role for SET in Galpha(12)-mediated signaling pathways and a role for Galpha(12) in the regulation of the leukemia-associated SET-protein expression.     

Expression of Gab1 lacking the pleckstrin homology domain is associated with neoplastic progression

An in vitro transformation system of carcinogen-treated Syrian hamster embryo (SHE) cell cultures represents multistep genetic and nongenetic changes that develop during the neoplastic progression of normal cells to tumor cells in vivo. During this neoplastic progression, SHE cells demonstrate an altered response to epidermal growth factor (EGF). In the present report, we examined the role of the adapter protein Gab1 (Grb2-associated binder-1) in the neoplastic progression of SHE cells. We used two asbestos-transformed SHE cell clones in different neoplastic stages: a 10W+8 clone, which is immortal and retains the ability to suppress the tumorigenicity of tumor cells in cell-cell hybrid experiments, and a 10W-1 clone, which has lost this tumor suppressor ability. 10W+8 cells expressed full-length 100-kDa Gab1 and associated 5.2-kb mRNA. Upon repeated cell passaging, 10W-1 cells showed increasing expression of a novel 87-kDa form of Gab1 as well as 4.6-kb mRNA with diminishing expression of the original 100-kDa Gab1. cDNA encoding the 87-kDa Gab1 predicts a form of Gab1 lacking the amino-terminal 103 amino acids (Gab1(Delta1-103)), which corresponds to loss of most of the pleckstrin homology (PH) domain. Gab1(Delta1-103) retains the ability to be phosphorylated in an EGF-dependent manner and to associate with the EGF receptor and SHP-2 upon EGF stimulation. The endogenous expression of Gab1(Delta1-103) in 10W-1 cells appeared closely related to EGF-dependent colony formation in soft agar. Moreover, transfection and expression of Gab1(Delta1-103), but not Gab1, in 10W+8 cells enhanced their EGF-dependent colony formation in soft agar. These results demonstrate that Gab1 is a target of carcinogen-induced transformation of SHE cells and that the expression of a Gab1 variant lacking most of the PH domain plays a specific role in the neoplastic progression of SHE cells.     

Effect of src infection on long-term marrow cultures: increased self-renewal of hemopoietic progenitor cells without leukemia

Long-term marrow cultures prepared from mice have been infected with a molecular recombinant of Rous sarcoma virus and murine amphitropic leukemia virus. This resulted in introduction of the src gene into the cultured cells and expression of its protein kinase function. The infected cultures displayed an altered balance in the accumulation of cells in different compartments of granulocyte differentiation. There was a dramatic increase in the stem cell (CFU-S) compartment and the committed progenitor cell (GM-CFC) compartment and a decrease in mature granulocytes. The altered balance appears to be caused by intrinsic alterations in the CFU-S and GM-CFC themselves, which increase their "self-renewal" capacity at the expense of cell differentiation. Remarkably, unlike its effects in other systems, src did not produce a neoplastic transformation of the hemopoietic cells.     

Cell cycle-related proteins: a flow cytofluorometric study in human tumors

We used 2-parameter flow cytometry (FCM) to investigate the relationship between the cell cycle phases and 3 proteins whose expression is known to increase in proliferating cells: the surface antigen transferrin receptor (Trf-r), the "cyclin" (a proliferating cell nuclear antigen, PCNA), and the nuclear antigen recognized by the monoclonal antibody (MoAb) Ki-67. FITC-labeled antibodies against Trf-r, PCNA, and the Ki-67-reactive antigen, as well as propidium iodide-DNA distribution, were simultaneously measured on human leukemia HL-60 and K562, and breast carcinoma MCF-7 cell lines and on fresh human leukemic and glioblastoma cells. The 70% ethanol fixation for Trf-r and PCNA and the 95% acetone fixation for Ki-67 plus permeabilization (with 0.1% and 1% Triton X100, respectively, for the surface and the nuclear antigens) produced cell suspensions with negligible cell clumping, high-quality DNA profiles, and bright specific immunofluorescent staining. The investigated proteins have different relationships with the proliferative state of the cell. Trf-r is expressed mainly at the transition from G0/G1 to S-phase. PCNA expression is prominent in late G1 and through S-phase and decreases in G2-M. The Ki-67-reactive antigen is widely distributed in G1, S, and G2-M phases. Knowledge regarding the relationships between proliferation-associated antigens and cell cycle phase in normal and neoplastic cells could improve our understanding of the mechanisms underlying growth regulation and neoplastic transformation. Bivariate FCM is an easy method for obtaining these data from large numbers of cells.     

Late ROS accumulation and radiosensitivity in SOD1-overexpressing human glioma cells

This study investigates the hypothesis that CuZn superoxide dismutase (SOD1) overexpression confers radioresistance to human glioma cells by regulating the late accumulation of reactive oxygen species (ROS) and the G(2)/M-checkpoint pathway. U118-9 human glioma cells (wild type, neo vector control, and stably overexpressing SOD1) were irradiated (0-10 Gy) and assayed for cell survival, cellular ROS levels, cell-cycle-phase distributions, and cyclin B1 expression. SOD1-overexpressing cells were radioresistant compared to wild-type (wt) and neo vector control (neo) cells. Irradiated wt and neo cells showed a significant increase (approximately twofold) in DHE fluorescence beginning at 2 days postirradiation, which remained elevated at 8 days postirradiation. Interestingly, the late accumulation of ROS was suppressed in irradiated SOD1-overexpressing cells. The increase in ROS levels was followed by a decrease in cell growth and viability and an increase in the percentage of cells with sub-G(1) DNA content. SOD1 overexpression enhanced radiation-induced G(2) accumulation within 24 h postirradiation, which was accompanied by a decrease in cyclin B1 mRNA and protein levels. These results support the hypothesis that long after radiation exposure a "metabolic redox response" regulates radiosensitivity of human glioma cells.     

Ruthenium red binding to cell coat in neoplastic neurogenic cell lines in culture.

The cell coat of cultivated fetal rat brain cells as well as malignant rat neurogenic cell lines in culture were studied by transmission electron microscopy with the ruthenium red staining technique. Some of the transformed cell lines demonstrated alteration in the bindng properties of ruthenium red to the cell surface. Otherwise no significant correlation between the visualized cell coat thickness and neoplastic transformation was noted.     

Rapid postradiation recovery of yeasts: the relationship to gamma-induced reciprocal mitotic recombination and gene conversion

gamma-induced reciprocal mitotic recombination and gene conversion have been studied under conditions inhibiting "rapid" postirradiation recovery of diploid yeast Saccharomyces cerevisiae. It turned out that, if the first postirradiation cell division occurs at higher KCl concentrations ("rapid" postirradiation recovery is inhibited), the frequency of mitotic reciprocal recombination within the gene ADE2-centromere region decreases. Keeping of irradiated cells (in the G1 phase of the cell division cycle) in water at 28 degrees C prior to plating on the selective agar containing 1.5 M KCl leads to smaller frequency of gene conversion lys2-25/lys2-22----Lys+, as compared with that for the cells immediately plated on the selective agar. Correlation has been found between the coefficient of gene conversion frequency decrease, due to postirradiation keeping in water, and "rapid" recovery efficiency. Interpretation of the data is based on the hypothesis that recombination repair of DNA double-strand breaks induced by ionizing radiation is responsible for "rapid" postirradiation recovery.     

Loss of LETS protein is not a marker for salivary gland or bladder epithelial cell transformation

LETS protein was demonstrated by indirect immunofluorescence techniques in adult mouse submandibular gland and bladder epithelial cells at various stages during neoplastic transformation, after the application of a chemical carcinogen in vitro. There was no clear relationship between transformation and the loss of LETS protein; most normal and preneoplastic epithelium lacked the distinctive fibrillar distribution of fluorescent staining. In contrast, some carcinoma-producing cell lines did possess appreciable amounts of LETS protein.     

Differentiation-dependent expression of lectin binding sites on normal and neoplastic keratinocytes in vivo and in vitro.

We used lectins as probes to demonstrate the composition of membrane carbohydrates of canine keratinocytes in various functional stages and various degrees of differentiation. Keratinocytes during normal epidermal turnover were compared by lectin immunohistochemistry to cells of hyperplastic epidermis and neoplastic keratinocytes. Three types of epidermal tumors and oral squamous cell carcinomas were examined. In addition, two in vitro tissue culture systems for keratinocytes were studied and compared with in vivo epithelium. In normal skin, PNA reacted only weakly with basal cells, whereas in hyperplastic skin basal cells bound this lectin strongly, demonstrating increasing expression of PNA binding sites with increasing thickness of the stratified squamous epithelium. ConA bound to basal cell tumors only. In oral squamous cell carcinomas, the expression of distinct lectin binding sites correlated with certain histological growth patterns, e.g., UEA-I reacted with highly invasive tumors but not with tumors showing a solid growth pattern. Using cell surface iodination and polyacrylamide gel electrophoresis, distinct differences in cell membrane protein expression were demonstrated between normal and neoplastic keratinocytes. SDS-polyacrylamide gel electrophoresis of cultured normal and neoplastic keratinocytes revealed several cell surface proteins that are specific for either cell type. Neoplastic cells specifically express a 140 KD lectin binding cell surface glycoprotein. The results of this study show that lectin binding patterns of keratinocytes are dependent on the functional state and the degree of differentiation of the cells and demonstrate correlation of some histological growth patterns with distinct lectin binding phenotypes, suggesting association of expression of cell membrane carbohydrate moieties with growth patterns. In addition, close similarities between "lifted cultures" grown at the air-liquid interface and native tissue demonstrate the value of this culture system as a model for differentiated stratified squamous epithelium.     

Differential distributions of CSE1L/CAS and E-cadherin in the polarized and non-polarized epithelial glands of neoplastic colorectal epithelium

Colorectal glands are important functional organs in colorectal tissue and are also the origin of colorectal carcinomas. Epithelial cell polarization of colorectal glands is related to structural integrity and physiological functions of colorectal glands as well as colorectal carcinoma formation. The cellular apoptosis susceptibility (CSE1L/CAS) protein has been shown to induce polarity formation of human colorectal cells in cell culture. E-cadherin expression in epithelial cells is crucial for the establishment and maintenance of epithelial cell polarity. In this study we examined the distributions of CSE1L and E-cadherin in the epithelial glands of normal and neoplastic colorectal epithelium and correlated these to polarity formation in the colorectal glands. Our results showed that CSE1L was differentially stained in the epithelial glands of neoplastic colorectal epithelium, and the staining was related to gland epithelial cell polarization and E-cadherin distribution. CSE1L was associated E-cadherin in GST pull-down experiments and immunoprecipitation assays. Basolateral staining of CSE1L and E-cadherin were seen in the polarized glands of normal and neoplastic colorectal epithelium. Absence of basolateral CSE1L staining in neoplastic epithelium glands was associated with loss of gland epithelial cell polarity, and this was parallel with E-cadherin staining. The non-polarized areas in epithelium glands showed a patchy staining for CSE1L and E-cadherin. These results indicate that examination of CSE1L and E-cadherin distribution in colorectal epithelium glands may be valuable for evaluating the malignance of colorectal disease.     

HIV-1 Tat protein induces glial cell autophagy through enhancement of BAG3 protein levels

BAG3 protein has been described as an anti-apoptotic and pro-autophagic factor in several neoplastic and normal cells. We previously demonstrated that BAG3 expression is elevated upon HIV-1 infection of glial and T lymphocyte cells. Among HIV-1 proteins, Tat is highly involved in regulating host cell response to viral infection. Therefore, we investigated the possible role of Tat protein in modulating BAG3 protein levels and the autophagic process itself. In this report, we show that transfection with Tat raises BAG3 levels in glioblastoma cells. Moreover, BAG3 silencing results in highly reducing Tat- induced levels of LC3-II and increasing the appearance of sub G0/G1 apoptotic cells, in keeping with the reported role of BAG3 in modulating the autophagy/apoptosis balance. These results demonstrate for the first time that Tat protein is able to stimulate autophagy through increasing BAG3 levels in human glial cells.     

Mechanism of the decrease in the major cell surface protein of chick embryo fibroblasts after transformation.

The major cell surface glycoprotein of cultured chick embryo fibroblasts (CSP, a LETS protein) is substantially decreased after neoplastic transformation. We investigated the regulation of this glycoprotein by determining the kinetics of CSP biosynthesis, transit to the cell surface, and degradation before and after transformation by Rous sarcoma virus. CSP synthesis, as measured by immunoprecipitation after pulse-labeling with ¹⁴C-leucine, is decreased 3–6 fold after transformation by the Bryan high titer, Schmidt-Ruppin and temperature-sensitive ts68 and T5 strains of Rous sarcoma virus. Steady state quantities of CSP in intracellular pools are also decreased 4–5 fold after transformation. However, the rate at which newly synthesized CSP is processed and exported to the cell surface is similar before and after transformation.Degradation and release of CSP from cells were measured after labeling for 24 hr. The half-life of CSP on normal cells is 36 hr and is decreased to 16–26 hr after transformation. The absolute amount of intact CSP released into the culture medium is decreased 3 fold after transformation; these amounts, however, represent losses of approximately 20 and 40% of the total CSP synthesized by normal and transformed cells, respectively. These results indicate that the major mechanism for the decrease in CSP after transformation is reduction in its biosynthesis, although increased degradation and loss from the cell surface also contribute significantly. These changes can account for the observed 5–6 fold decreases in cell-associated CSP after transformation of chick embryo fibroblasts.