Restored gap junctional communication in non-tumorigenic HeLa-normal human fibroblast hybrids

Gap junctional intercellular communication (GJIC) has been implicated in homeostasis, development, differentiation, wound healing or regeneration and adaptive responses of differentiated cells. The dysfunction of homologous or heterologous GJIC has been associated with the tumorigenic phenotype. Restoration of growth control and the suppression of the tumorigenic phenotype have been previously associated with the up-regulation of GJIC by various anti-tumorigenic chemicals or transfection of connexin genes into tumor cells. To test the hypothesis that 'tumor suppressor' genes may be associated with the up-regulation of GJIC, we tested clones of tumorigenic HeLa, several non-tumorigenic HeLa-normal human fibroblast somatic cell hybrids and a tumorigenic segregant of one of the non-tumorigenic hybrids for GJIC. The parental HeLa cells (D98 AH.2) had no detectable GJIC but expressed detectable connexin 43 transcripts, while the non-tumorigenic HeLa-human fibroblast hybrids, which contained the chromosome 11 from the normal human fibroblast (CGL-1, CGL-2, ESH15 and EHS15c1), expressed ample connexin 43 transcripts and showed proficient GJIC. The tumorigenic segregant (CGL-3) from the non-tumorigenic HeLa-human fibroblast hybrid showed no GJIC or connexin 43. These results show that the presence of GJIC is closely linked to the suppression of the tumorigenic phenotype in the HeLa-human fibroblast hybrid and further suggest that GJIC may be associated with the mechanisms of tumor suppression. The mechanism by which the tumor suppressor gene(s) on the normal chromosome in the HeLa-human fibroblasts induces the up-regulation of connexin 43 is not yet explained.

Involvement of tyrosine phosphorylation of p185(c-erbB2/neu) in tumorigenicity induced by X-rays and the neu oncogene in human breast epithelial cells

Ionizing radiation is the exogenous agent best proven to induce breast cancer. c-erbB2/neu amplification and overexpression are known to occur in breast cancer and are correlated with aggressive tumor growth and poor prognosis. We have developed simian virus 40-immortalized cell lines from normal human breast epithelial cells (HBECs) with luminal and stem-cell characteristics. In this study, we examined whether x-rays and a mutated neu oncogene are capable of inducing tumorigenicity in these cells. The results indicated that x-rays were effective in converting immortal non-tumorigenic HBECs to weakly tumorigenic cells that then could be transformed to highly tumorigenic cells by the neu oncogene. The in vitro growth of these tumorigenic cells was significantly faster than that of the parental non-tumorigenic cells in growth factor- and hormone-supplemented or -depleted media. The neu oncogene, however, had no tumorigenic effect on immortal non-tumorigenic cells. The expression of p185(c-erb82/neu) was elevated in neu-transduced immortal or weakly tumorigenic cell lines. However, only in the latter was p185(c-erbB2/neu) found to be phosphorylated at tyrosine residues. Thus, x-rays appear to induce a genetic alteration that confers weak tumorigenicity on immortal HBECs and interacts with p185(c-erbB2/neu) directly or indirectly to give rise to fast-growing tumors.

Cell-cell communication in carcinogenesis

To explain the complex carcinogenic process by which a single normal cell in human beings can be converted to an invasive and metastatic cancer cell, a number of experimental findings, epidemiological observations and their associated hypothesis/theories have been integrated in this review. All cancers have been generally viewed as the result of a disruption of the homeostatic regulation of a cell's ability to respond appropriately to extra-cellular signals of the body which trigger intra-cellular signal transducting mechanisms which modulate gap junctional intercellular communication between the cells within a tissue. Normal homeostatic control of these three forms of cell communication determines whether: (a) the cell remains quiescent (Go); (b) enters into the cell proliferation phase; (c) is induced to differentiate; (d) is committed to apoptose; or (e) if it is already differentiated, it can adaptively respond. During the evolution from single cell organisms to multicellular organisms, new cellular/biological functions appeared, namely, the control of cell proliferation ("contact inhibition"), the appearance of the process of differentiation from committed stem cells of the various tissues and the need for programmed cell death or apoptosis. Interestingly, cancer cells have been characterized as cells: (a) having been derived from a stem-like cell; (b) without their ability to control cell growth or without the ability to contact inhibit; (c) which can not terminally differentiate under normal conditions; and (d) having altered ability to apoptosis under normal conditions. During that evolutionary transition from the single cell organism to the multicellular organism, many new genes appeared to accompany these new cellular functions. One of these new genes was the gene coding for a membrane associated protein channel (the gap junction) which between coupled cells, allowed the passive transfer on ions and small molecular weight molecules. A family of over a dozen of these highly evolutionarily-conserved genes (the connexin genes) coded for the connexin proteins. A hexameric unit of these connexins in one cell (a connexon) couples with a corresponding connexon in a contiguous cell to join the cytoplasms. This serves to synchronize either the metabolic or electrotonic functions of cells within a tissue. Most normal cells within solid tissues have functional gap junctional intercellular communication (GJIC) (exceptions are free-standing cells such as red blood cells, neutrophils, and several, if not all, the stem cells). On the other hand, the cancer cells of solid tissues appear to have either dysfunctional homologous or heterologous GJIC. Therefore, among the many differences between a cancer cell and its normal parental cell, the carcinogenic process involves the transition from a normal, GJIC-competent cell to one that is defective in GJIC. The review examines how GJIC can be either transiently or stably modulated by endogenous or exogenesis chemicals or by oncogenes and tumor suppressor genes at the transcriptional, translational, or posttranslational levels. It also uses the gap junction as the biological structure to facilitate cellular/tissue homeostasis to be the integrator for the "stem cell" theory, "disease of differentiation theory", "initiation/promotion/progression" concepts, nature and nurture concept of carcinogenesis, the mutation/ epigenetic theories of carcinogenesis, and the oncogene/ tumor suppressor gene theories of carcinogenesis. From this background, implications to cancer prevention and cancer therapy are generated.

Hierarchical and cybernetic nature of biologic systems and their relevance to homeostatic adaptation to low-level exposures to oxidative stress-inducing agents

During evolution in an aerobic environment, multicellular organisms survived by adaptive responses to both the endogenous oxidative metabolism in the cells of the organism and the chemicals and low-level radiation to which they had been exposed. The defense repertoire exists at all levels of the biological hierarchy--from the molecular and biochemical level to the cellular and tissue level to the organ and organ system level. Cells contain preventive antioxidants to suppress oxidative damage to membranes. Cells also contain proteins and DNA; built-in redundancies for damaged molecules and organelles; tightly coupled redox systems; pools of reductants; antioxidants; DNA repair mechanisms and sensitive sensor molecules such as nuclear factor kappa beta; and signal transduction mechanisms affecting both transcription and post-translational modification of proteins needed to cope with oxidative stress. The biologic consequences of the low-level radiation that exceeds the background level of oxidative damage could be necrosis or apoptosis, cell proliferation, or cell differentiation. These effects are triggered by oxidative stress-induced signal transduction mechanisms--an epigenetic, not genotoxic, process. If the end points of cell proliferation, differentiation, or cell death are not seen at frequencies above background levels in an organism, it is unlikely that low-level radiation would play a role in the multistep processes of chronic diseases such as cancer. The mechanism linked to homeostatic regulation of proliferation and adaptive functions in a multicellular organism could provide protection of any one cell receiving deposited energy by the radiation tract through the sharing of reductants and by triggering apoptosis of target stem cells. Examples of the role of gap junctional intercellular communication in the adaptive response of cells and the bystander effect illustrate how the interaction of cells can modulate the effect of radiation on the single cell.

Bay or baylike regions of polycyclic aromatic hydrocarbons were potent inhibitors of Gap junctional intercellular communication

Many polycyclic aromatic hydrocarbons (PAHs) are known carcinogens, and a considerable amount of research has been devoted to predicting the tumor-initiating potential of PAHs based on chemical structure. However, there has been little research into the effects of PAHs on the epigenetic events of tumor promotion and no structural correlation has been made thereof. Gap junctional intercellular communication (GJIC) activity was used in this study as an epigenetic biomarker to determine the structure-activity relationships of twelve different PAHs. The PAHs used were naphthalene, 1-methylnaphthalene, 2-methylnaphthalene, anthracene, 1-methylanthracene, 2-methylanthracene, 9-methylanthracene, 9, 10-dimethylanthracene, phenanthrene, fluorene, 1-methylfluorene, and fluoranthene. Results showed that PAHs containing bay or baylike regions inhibited GJIC more than did the linear PAHs. The nonnaphthalene PAHs were not cytotoxic as determined by a vital dye uptake assay, but the naphthalene compounds were cytotoxic at the higher doses, indicating that the down regulation of GJIC by these naphthalenes could be a consequence of general membrane damage. Inhibition of GJIC by all the inhibitory PAHs was reversed when the cells were refreshed with PAH-free growth medium. Inhibition of GJIC occurred within 0.5-5 min and correlated with the aqueous solubility of the PAHs. The present study revealed that there are structural determinants of epigenetic toxicity as determined by GJIC activity.

Oxidative stress, signal transduction, and intercellular communication in radiation carcinogenesis

During the evolution of multicellular organisms, survival in an aerobic environment came about by adaptive responses, both to the endogenous oxidative metabolism within the cells of the organism as well as the chemicals and low-level radiation to which they are exposed. In addition to defense mechanisms shared with single-cell organisms, multicellular organisms are equipped with gap junctions which allow electrotonic and/or metabolic synchronization of processes between coupled cells. The connexin genes, which code for the proteins comprising the gap junctions, provide homeostatic regulation of cell proliferation, differentiation, and adaptive responses of individual cells through a mechanism of "gap junctional intercellular communication." The biological consequences of the response of a multicellular organism to low-level radiation exceeding the background level of oxidative damage to a cell in a tissue could be apoptosis, cell proliferation, or cell differentiation.

Protection of herpes simplex virus thymidine kinase-transduced cells from ganciclovir-mediated cytotoxicity by bystander cells: the Good Samaritan effect

Although considerable attention has been directed in the field of gene therapy toward elucidating the mechanism by which a transduced cell could kill a bystander cell, little is known about how bystander cells may affect transduced cells. We hypothesized that bystander cells, particularly if they were capable of gap junctional communication, could protect cells transduced with the herpes simplex virus thymidine kinase (HSV-TK) from ganciclovir (GCV)-induced cytotoxicity. To test this hypothesis, we used a rat hepatocyte cell line (WB) that can carry out efficient gap junctional communication, a WB clone transduced with HSV-TK (WB-TK), and a communication-incompetent subclone of WB cells (aB1). We cocultured WB-TK cells with either WB or aB1 cells, treated them with GCV, and then plated the cells into selective media that permitted us to quantify independently the surviving fraction of WB-TK cells or bystander cells. We found that WB bystander cells conferred up to a 1000-fold protection on WB-TK cells treated with GCV. aB1 cells conferred detectable, but significantly less, protection. These findings demonstrate that herpes simplex virus thymidine kinase-transduced cells can be significantly protected by bystander cells, particularly those that can carry out gap junctional communication. Whether this "Good Samaritan" effect improves the overall efficacy of gene therapy, by prolonging the survival of the source of toxic metabolites, or decreases effectiveness by increasing the survival of transduced cells will need to be determined in vivo.

The causes of cancer: implications for prevention and treatment

The final clinical manifestation of cancer is a result of complex series of changes in a single cell. This review summarizes some of the new concepts and hypotheses that explain the evolution of cancers. The emphasis is on cancer as a disease of the stem cells within a tissue that undergo initiation as a result of mutational insult to one or more genes that are critical for cell growth. During the second stage (promotion stage) the initiated cells acquire proliferative capacity due to epigenetic changes, i.e., altered expression of genes whose products play a central role in signal transduction. This requires continued exposure to agents and events causing such changes. This stage is, therefore, reversible and the various components of this stage are central targets for the development of mechanism based anti-cancer drugs. During the stage of progression, the neoplastic lesions acquire additional genetic alterations and become clinically manifestable malignant neoplasms. At the biochemical and molecular level, neoplastic transformation involves aberrations in the expression and regulation of oncogenes, tumor suppression genes, transcription factors and components of the cell signal transduction cascades. The understanding of the various cellular biochemical and molecular events that metamorphose a normal cell into a cancer cell is central to the development of rational new drugs that are targeted against the various components. Such drugs in combination with the conventional chemotherapeutic agents that are currently used, provide a more effective control of cancer without the risk of toxic side effects.

Expression of estrogen receptors in a normal human breast epithelial cell type with luminal and stem cell characteristics and its neoplastically transformed cell lines

Although approximately two-thirds of breast cancers are estrogen receptor (ER)-positive, only a small proportion of epithelial cells in the mammary gland express the ER. The origin of the ER-positive breast cancers is unknown. Recently, we have developed a culture method to grow two morphologically and antigenically distinguishable types of normal human breast epithelial cells (HBEC) derived from reduction mammoplasty. In this report, we studied the expression of ER in these two types of cells and their transformed cell lines. The results indicate that Type I HBEC with luminal and stem cell characteristics expressed a variant ER (approximately 48 kd) by Western blot analysis. This variant ER contains a deletion in the DNA binding domain (exon 2) as revealed by RT-PCR analysis. The lack of the DNA-binding domain of the variant ER was also confirmed by the ER-estrogen responsive element binding assay, as well as by the immunofluorescence staining of the ER using anti-ER antibodies which recognize either the C-terminal or N-terminal region. In contrast, Type II HBEC with basal epithelial phenotype are ER-negative. Simian virus 40 (SV40) transformed Type I and Type II HBEC lines also expressed the variant ER. Tumors formed in athymic nude mice by in vitro transformed tumorigenic Type I cell lines, however, expressed a high level of wild type ER which was undetectable in these cells grown in vitro before and after tumor formation. Thus, there appears to be a differential ER mRNA splicing between the in vitro and in vivo mileu.

Stimulation of cell proliferation and inhibition of gap junctional intercellular communication by linoleic acid

The effect of linoleic acid (LA) on gap-junction permeability, connexin 43 mRNA level, protein level, and phosphorylation, and the numbers of gap-junctional membrane plaques were studied in the rat liver epithelial cell line WB-F344 to determine whether changes in these parameters correlated with the enhanced cell growth and the inhibition of gap-junction function. When cultured in a medium with low serum (1%), these cells exhibited a slower growth rate than in the high serum medium (7%). Addition of linoleic acid (0.01-3 mg/ml) to the low serum medium increased the growth rate and inhibited gap junctional intercellular communication (GJIC) in a dose-dependent manner. In a comparison of short-term and long-term treatments with LA, GJIC in short-term treated (1 h) WB cells was inhibited at 3 mg/ml LA but readily recovered by washing and removing LA from cells, whereas GJIC in long-term treated (6 days) WB cells did not recover by washing and removing LA from WB cells. Western blot analysis of connexin 43 showed that a short-term incubation with linoleic acid increased the relative amount of unphosphorylated connexin 43 protein, but a long-term incubation with linoleic acid decreased the amount of unphosphorylated connexin 43 protein and increased the relative amount of hyperphosphorylated connexin 43 protein. Connexin 43 and p53 mRNA levels decreased in a time- and dose-dependent manner in linoleic acid-treated cells. These results suggest that growth stimulation and gap junctional intercellular communication inhibition of rat liver epithelial cells by linoleic acid may be mediated in part through modulation of p53 expression and function.

Hydrogen peroxide inhibits gap junctional intercellular communication in glutathione sufficient but not glutathione deficient cells

Cell to cell communication via gap junctions is essential in the maintenance of the homeostatic balance of multicellular organisms. Aberrant intercellular gap junctional communication (GJIC) has been implicated in tumor promotion, neuropathy and teratogenesis. Oxidative stress has also been implicated in similar pathologies such as cancer. We report a potential link between oxidative stress and GJIC. Hydrogen peroxide, a known tumor promoter, inhibited GJIC in WB-F344 rat liver epithelial cells with an I50 value of 200 microM. Inhibition of GJIC by H2O2 was reversible as indicated by the complete recovery of GJIC with the removal of H2O2 via a change of fresh media. Free radical scavengers, such as t-butyl alcohol, propylgallate, and Trolox, did not prevent the inhibition of GJIC by H2O2, which indicated that the effects of H2O2 on GJIC was probably not a consequence of aqueous free radical damage. The depletion of intracellular GSH reversed the inhibitory effect of H2O2 on GJIC. The treatment of glutathione-sufficient cells with H2O2 resulted in the hyperphosphorylation of connexin43, which is the basic subunit of the hexameric gap junction protein, as determined by Western blot analysis. TPA, a well-known tumor promoter, also inhibits GJIC via hyperphosphorylation of GJIC, which is a result of protein kinase-C activation. However, H2O2 also induced hyperphosphorylation in GSH-deficient cells that had normal rates of GJIC. Therefore, the mechanism of GJIC inhibition must be different from the TPA-pathway and involves GSH.

The effects of anthracene and methylated anthracenes on gap junctional intercellular communication in rat liver epithelial cells

Polycyclic aromatic hydrocarbons (PAHs), many of which are known carcinogens, are derived from the pyrolysis of organic materials. A rich source of PAHs is cigarette smoke, which contains methylated anthracenes and phenanthrenes as the predominant PAHs. The tumor-promoting activity of cigarette smoke has been well documented. The down-regulation of gap junction intercellular communication (GJIC) by nongenotoxic chemicals and several oncogenes has been implicated in tumor promotion. Therefore, we determined the effects of the three isomers of methylanthracene on GJIC in WB-F344 rat liver epithelial cells. Anthracene and 2-methylanthracene did not significantly inhibit GJIC, whereas anthracene methylated in the 1 or 9 position reversibly inhibited GJIC with I50 values of 22 and 36 microM, respectively. Inhibition occurred within 15 min. In conclusion, the biological effect of methylanthracene depends on the ring position of the methyl group, and these inhibitory isomers could play a potential role in tumor promotion of methylated PAH-rich mixtures such as cigarette smoke and crude oil products.

Localization and function of the connexin 43 gap-junction protein in normal and various oncogene-expressing rat liver epithelial cells

Clones of rat liver epithelial cells genotypically altered by mutation or by a variety of oncogenes were analyzed by microinjection-dye transfer, immunofluorescence confocal microscopy, and western blotting to determine at what level and to what degree these transformations disrupted gap-junctional intercellular communication (GJIC) mediated by connexin 43 (Cx43). Compared with normal rat liver epithelial cells, cells neoplastically transformed by src, neu, ras, and myc/ras all displayed reduced degrees of GJIC, reduced levels of membrane-associated Cx43 plaques, and hypophosphorylation of Cx43. Confocal analysis further demonstrated that the Cx43 protein was localized, at least in part, to the nucleus rather than to the plasma membrane in the src- and neu-transformed cells, but not in the ras- and myc/ras-transformed cells. Nuclei isolated from WB-neu cells showed substantially higher levels of Cx43 on western blotting than did nuclei from WB-neo control cells, supporting the idea that the nuclear-localized immunopositive material detected by confocal microscopy was Cx43 protein. In a GJIC-deficient mutant rat liver epithelial cell line containing normal numbers of plasma membrane-localized Cx43 plaques that appeared to be reduced in size, the Cx43 protein was also found to be hypophosphorylated. Cells overexpressing myc, on the other hand, displayed a normal degree of GJIC, increased levels of plasma membrane-localized Cx43 plaques, and hyperphosphorylation of the Cx43 protein. Cells expressing raf, previously shown to be GJIC competent, showed Cx43 immunostaining patterns similar to those in normal cells, whereas a cell line established from a tumor induced by injection of these raf-expressing cells into a mouse showed a marked reduction in GJIC and plasma membrane-associated Cx43 immunostaining. These data suggest that altered localization of the gap-junction protein Cx43, mediated in part by changes in the phosphorylation of this protein, contributes to the disruption of GJIC in neoplastically transformed rat liver epithelial cells.

Upregulation of gap junctional intercellular communication in immortalized gonadotropin-releasing hormone neurons by stimulation of the cyclic AMP pathway

Increased gap junctional intercellular communication induced by agents that stimulate the adenylyl cyclase/cAMP pathway was observed in the GnRH-secreting neuronal cell line, GT1-7, and possible underlying mechanisms were examined. A 24-hour treatment of GT1-7 neurons with 100 microM dibutyryl cAMP + 100 microM IBMX or with 2 microM forskolin increased by greater than 2-fold the percentage of cells that were dye coupled, using the noninvasive dye coupling assay, fluorescent recovery after photobleaching (FRAP). Longer treatment times (48 h) and higher concentrations of dibutyryl cAMP (500 microM) did not further increase the percentage of dye-coupled cells, while there was no increase in dye coupling observed between untreated cells and cells treated for 2 h or less. The increase in dye coupling induced by dibutyryl cAMP/IBMX was inhibited by octanol or dieldrin, agents known to block gap junction-mediated intercellular coupling in other cell types. Western blot analysis of total protein or membrane protein-enriched extracts revealed no apparent difference in the cellular levels of connexin 26, a connexin subtype previously shown to be expressed by GT1-7 cells, between untreated cells and cells treated for 24 h with dibutyryl cAMP/IBMX or forskolin. In addition, expression of connexin 32 or 43 protein before or after treatment was not detected. On the other hand, a dramatic increase in both the number of neurites and neurites that immunostained positive for connexin 26 was observed in dibutyryl cAMP/IBMX-treated cells. We hypothesize that the observed increase in dye coupling between GT1-7 neurons following stimulation of the adenylyl cyclase/cAMP pathway results from an augmentation of cell-cell contacts due to an increased number of neurites containing gap junctional plaques, possibly through an effect on cellular differentiation.

Pulse treatment with the tumor promoter TPA delays the onset of desensitization response and prolongs the inhibitory effect on gap junctional intercellular communication of a rat liver epithelial cell line WB F-344

The tumor promoter 12-O-tetradecanoylphorbol-13-acetate (TPA) is an inhibitor of gap junctional intercellular communication (GJIC) of the rat liver epithelial cell line, WB F-344. We have previously reported that prolonged treatment of the WB cells with TPA (10 ng/ml) caused a reversal of the inhibition of GJIC that was initially induced (Oh, S.Y., et al. (1988) Carcinogenesis, 9, 135-139). Under this condition, addition of fresh TPA did not inhibit GJIC of these cells. In the present investigation we examined whether pulse exposure to TPA delays the onset of this desensitization response. Cultures were treated for 5 or 15 min with TPA and shifted to normal medium. Intercellular communication was measured at 15 min, 1 h and 6 h after the 5 or 15 min pulse treatments. Under these pulse treatment conditions, GJIC of the cells was markedly inhibited for up to 4 h and gradually reverted to near control levels by 6-8 h. At every sixth hour of pulse treatment the cells were given an additional pulse treatment (5 or 15 min) and the inhibitory effect of TPA on the GJIC of the cells was assayed 15 min after each such treatment. The results clearly showed that, when the cells were treated with 10 ng/ml TPA for 5 or 15 min every 6 h they maintained their sensitivity to the inhibitory effect of TPA on GJIC. This response to TPA was sustained for a considerably longer time when the duration of the pulse treatment was 5 min. Our data suggested that pulse exposure to TPA delays the desensitization response normally observed in prolonged treatment regimens and that this delay is possibly due to maintenance of the TPA activatable pool of protein kinase C under these conditions.

Localization and function of the connexin 43 gap-junction protein in normal and various oncogene-expressing rat liver epithelial cells

Clones of rat liver epithelial cells genotypically altered by mutation or by a variety of oncogenes were analyzed by microinjection-dye transfer, immunofluorescence confocal microscopy, and western blotting to determine at what level and to what degree these transformations disrupted gap-junctional intercellular communication (GJIC) mediated by connexin 43 (Cx43). Compared with normal rat liver epithelial cells, cells neoplastically transformed by src, neu, ras, and myc/ras all displayed reduced degrees of GJIC, reduced levels of membrane-associated Cx43 plaques, and hypophosphorylation of Cx43. Confocal analysis further demonstrated that the Cx43 protein was localized, at least in part, to the nucleus rather than to the plasma membrane in the src- and neu-transformed cells, but not in the ras- and myc/ras-transformed cells. Nuclei isolated from WB-neu cells showed substantially higher levels of Cx43 on western blotting than did nuclei from WB-neo control cells, supporting the idea that the nuclear-localized immunopositive material detected by confocal microscopy was Cx43 protein. In a GJIC-deficient mutant rat liver epithelial cell line containing normal numbers of plasma membrane-localized Cx43 plaques that appeared to be reduced in size, the Cx43 protein was also found to be hypophosphorylated. Cells overexpressing myc, on the other hand, displayed a normal degree of GJIC, increased levels of plasma membrane-localized Cx43 plaques, and hyperphosphorylation of the Cx43 protein. Cells expressing raf, previously shown to be GJIC competent, showed Cx43 immunostaining patterns similar to those in normal cells, whereas a cell line established from a tumor induced by injection of these raf-expressing cells into a mouse showed a marked reduction in GJIC and plasma membrane-associated Cx43 immunostaining. These data suggest that altered localization of the gap-junction protein Cx43, mediated in part by changes in the phosphorylation of this protein, contributes to the disruption of GJIC in neoplastically transformed rat liver epithelial cells.

C-erbB2/neu transfection induces gap junctional communication incompetence in glial cells

Astrocytes form functional networks that participate in active signaling in which external stimuli are generated and amplified in many of the same ways as in neurons. Gap junctions between astrocytes offer the structural avenue by which the electrical and metabolic signals are propagated from one cell to another. Little is known about the trafficking, assembly, and degradation mechanisms of the major astrocytic gap junction protein connexin43. We have studied a glial cell line transfected with the C-erbB2/neu oncogene (neu+), finding severe interruption of gap junctional communication after stable transfection. Evidence from Western blotting and phosphorylation studies showed that the processing of connexin43 to its higher phosphorylated isoforms is disturbed. Confocal laser imaging indicates that the major deficit in the neu+ cells is attributable to a lack in plaque assembly of connexin43. Because the neu+ cells also lack N-CAM proteins and because work from others has indicated a close relationship between communication competence and constitutive CAM expression, our data suggest that expression of C-erbB2/neu oncogene alters cell-cell association via CAM proteins, which thereby affects gap junction plaque assembly and appropriate phosphorylation of connexin43.

Role of low-level ionizing radiation in multi-step carcinogenic process

In view of our current understanding of experimental in vitro and in vivo studies, as well as of the epidemiological data, carcinogenesis is the result of many endogenous and exogenous factors. No single factor "causes" cancer. A number of extant theories of carcinogenesis and of ionizing radiation's role in the process have been reviewed. An integration of the stem cell theory, the theory of "oncogeny as partially blocked ontogeny," the initiation/promotion/progression model of carcinogenesis, the oncogene/tumor suppressor gene theory, and mutation/epigenetic theories of carcinogenesis was attempted by linking all of them with the process of intercellular communication. This integration was done by examining how extra-, intra- and inter-cellular communication might he affected by the current known facts of the types of radiation-induced biological effects, such as gene and chromosomal mutations, cell killing, including apoptosis and epigenetic alterations of gene expression. Finally, an examination of the possible role of low-level radiation in the multi-step carcinogenetic process, which might have given rise to the excess cancers attributable to radiation exposure in the survivors of the atomic bombs, was attempted.

Characterization of ret oncogenic activation in MEN2 inherited cancer syndromes

Germline mutations of c-ret, encoding a receptor-type tyrosine kinase, were found to be associated with variants of multiple endocrine neoplasia type 2 (MEN2A, MEN2B), and familial medullary thyroid carcinoma. NIH/3T3 stable transfectants expressing RET with a mutation of MEN2A (MEN2A/RET) or MEN2B (MEN2B/RET) gained a transformed morphology, formed colonies in soft agar, and formed tumors in nude mice. These results confirmed that both MEN2A/RET and MEN2B/RET exert dominant transforming activities in NIH/3T3 cells. However, in contrast to their clinical manifestation, transfectants expressing MEN2A/RET exhibited a higher tumorigenicity in nude mice than transfectants expressing MEN2B/RET may depend on the presence of its ligand and/or substrates that are absent in NIH/3T3 cells. No change in the cellular localization of the mutated RET proteins was observed compared to c-RET. Interestingly, ret activation in NIT/3T3 cells appeared to be associated with up-regulation of homologous gap-junctional intercellular communication and increased expression of a gap-junctional protein, connexin43.

Inhibition of gap junctional intercellular communication in heptachlor- and heptachlor epoxide-treated normal human breast epithelial cells

Based on the concern of organochlorides in the environment and in human tissue, this study was designed to determine whether various noncytotoxic levels of heptachlor and heptachlor epoxide could inhibit, reversibly, gap junctional intercellular communication in human breast epithelial cells (HBEC). Cytotoxicity and gap junctional intercellular communication (GJIC) were evaluated by lactate dehydrogenase assay and fluorescence redistribution after photobleaching analysis, respectively. Both heptachlor and heptachlor epoxide were noncytotoxic up to 10 microg/ml. At this concentration, heptachlor and heptachlor epoxide inhibited GJIC of normal human breast epithelial cells after 1 h treatment. Within a 24 h treatment with heptachlor and heptachlor epoxide at 10 microg/ml, recovery of GJIC had not returned. GJIC completely recovered after a 12 h treatment of 1 microg/ml heptachlor epoxide, but it did not recover after a 24 h treatment of 1 microg/ml heptachlor. RT-PCR and Western blots were analyzed to determine whether the heptachlor or heptachlor epoxide might have altered the steady-state levels of gap junction mRNA and/or connexin protein levels or phosphorylation state. No significant difference in the level of connexin 43 (Cx43) message between control and heptachlor-treated cells was observed. Western blot analyses showed hypophosphorylation patterns in cells treated with 10 microg/ml heptachlor and heptachlor epoxide for 1 h with no recovery within 24 h. Immunostaining of Cx43 protein in normal HBEC indicated that heptachlor and heptachlor epoxide caused a loss of Cx43 from the cell membranes at noncytotoxic dose levels. Taken together, these results suggest that heptachlor and heptachlor epoxide can alter GJIC at the post-translational level, and that, under the conditions of exceeding a threshold concentration in the breast tissue containing 'initiated' cells for a long time and not being counteracted by anti-tumor-promoting chemicals, they could act as breast tumor promoters.

A comparison of the propensity for gene amplification between near-tetraploid and near-diploid V79 clones resistant to 150 nM methotrexate

Among various 150-nM methotrexate-resistant (MTXr) V79 clones isolated, we found that two near-tetraploid clones as well as a near-diploid clone with amplification in the dihydrofolate reductase (dhfr) gene readily developed resistant to 40 000 nM MTX within 3 months during stepwise increased MTX selection, while two near-diploid clones without gene amplification could not acquire resistance beyond 5000 nM MTX. Then, we studied how the clones increased the resistance to MTX, and compared the propensity for gene amplification among three types of clones. Dot blot analysis showed that the acquisition of the high levels of resistance to MTX observed in two near-tetraploid clones and a near-diploid clone with gene amplification was associated with amplification in the dhfr gene. The amplified dhfr gene was overexpressed at mRNA and protein levels in the clones. Southern blot analysis of Hind III- and Eco RI-digested DNA in the clones at the time when they became resistant to 10 000 nM MTX indicated that they amplified the dhfr gene fragments which existed in low amounts in parental V79 cells, and that no gross rearrangement of the amplified dhfr gene was detected. Furthermore, fluorescence in situ hybridization analysis showed that the amplified dhfr gene was located on one chromosome as cluster(s). On the other hand, two near-diploid clones without gene amplification did not show any amplification of the dhfr gene even at 5000 nM-MTX resistant stage. These combined results suggest that the near-tetraploid clone as well as the near-diploid clone with the dhfr gene amplification have genomic instability with the propensity for gene amplification during stepwise MTX selection, and have a similar process for the development of the dhfr gene amplification.

Inhibition of gap junctional intercellular communication in normal human breast epithelial cells after treatment with pesticides, PCBs, and PBBs, alone or in mixtures

Chemical pollutants in the Great Lakes have found their way through the food chain into humans because of their environmental persistence and lipophilicity. Some epidemiological studies have claimed an association between metabolites of 2,2-bis(p-chlorophenyl)-1,1,1-trichloroethane (DDT), polychlorinated biphenyls (PCBs), and polybrominated biphenyls (PBBs) and breast cancer, but others have reported no such association. We examined various halogenated hydrocarbons for their capacity to inhibit gap junctional intercellular communication (GJIC) in normal human breast epithelial cells (HBEC) when given as single compounds or as mixtures. The scrape-loading/dye transfer and fluorescent redistribution after photobleaching techniques were used to measure GJIC; immunostaining and Western and Northern analyses were performed on connexin 43 (Cx43) gap junction protein and message to determine how halogenated hydrocarbons might affect GJIC. DDT, dieldrin, and toxaphene inhibited GJIC in a dose-responsive manner after 90 min treatments. Dieldrin suppressed GJIC within 30 min with no recovery after 24 hr. Inhibition of GJIC by DDT and toxaphene was partially restored after 12 hr and fully restored after 24 hr. Several PCB and PBB congeners inhibited GJIC in a dose-responsive and time-dependent manner, but GJIC was almost restored to control values 24 hr after exposure. The highest concentrations of the individual chemicals that did not inhibit GJIC was determined, and mixtures containing two of these chemicals were tested for their ability to inhibit GJIC. Significant inhibition of GJIC was observed when cells were treated with a mixture of DDT and 2,4,5-hexachlorobiphenyl (2,4,5-HCB), dieldrin and 2,4,5-HCB, or dieldrin and 2,4,5-hexabromobiphenyl (2,4,5-HBB). These results indicate that halogenated hydrocarbons, alone or in specific combinations, can alter GJIC at the post-translational level. These results are consistent with the hypothesis that DDT, dieldrin, toxaphene, 2,3,4-HCB, 2,4,5-HCB, and 2,4,5-HBB could have tumor-promoting potential in human breast tissue.

Biomarkers for low-level exposure causing epigenetic responses in stem cells

Our current understanding of experimental in vitro and in vivo studies, as well as of epidemiological data, suggests that carcinogenesis is the result of many endogenous and exogenous factors interacting during a multi-step, multi-mechanism process. No single factor "causes" cancer. Carcinogenesis is known to involve both mutagenic and nonmutagenic processes. Therefore, the objective of this review is to examine how low dose exposure to ionizing radiation might contribute to the carcinogenic process and if measurable "biomarkers" might be used to monitor the susceptibility, exposure, biological consequence and clinical disease patterns attributable to ionizing radiation. While the primary biomarker for ionizing radiation has been DNA damage and genetic/chromosomal mutations, possible effects on apoptosis and epigenetic processes have been examined. The search for biomarkers of cytotoxic (apoptotic) and epigenetic events induced by low-level ionizing radiation was thought to be difficult in view of the fact that controlled apoptotic and epigenetic events occur constantly in a healthy body exposed to background radiation. In addition, if the stem cell is the target cell for low-level radiation exposure, detection of biomarkers in this small subpopulation of cells in any tissue places severe limitations on any practical noninvasive means to identify such biomarkers. Last, a critical re-examination of the cancer incidence data of the Hiroshima/Nagasaki A-bomb survivors is suggested in view of modifying factors such as caloric restriction and post-irradiation trauma/treatment that could affect the multi-stage nature of carcinogenesis.