Phorbol ester-stimulated phosphorylation of PU.1: association with leukemic cell growth inhibition.

PU.1, a member of the ets transcription factor family, has been previously shown to be necessary for tetradecanoylphorbol-13 acetate (TPA)-induced U937 leukemic cell maturation. We examined the effects of TPA on PU.1 content and PU.1 DNA binding activity in U937 cells. Unstimulated cells expressed PU.1 mRNA transcripts and TPA did not increase these levels. However, TPA treatment induced phosphorylation of PU.1. Gel-shift analysis using a labeled PU.1 oligomer showed that TPA induced a unique PU.1 binding activity. This binding activity was phosphorylation-dependent, as indicated by the ability of phosphatase treatment to abolish its detection. The PU.1 binding activity was generated at TPA-13 concentrations stimulating growth arrest and was blocked by the PKC inhibitor GF109203X, which antagonized TPA-induced growth inhibition. Bryostatin 1, another protein kinase C activator, induced only a modest degree of U937 growth inhibition and antagonized TPA-stimulated growth arrest. Bryostatin 1 was unable to induce this TPA-generated PU.1 binding activity. High bryostatin 1 concentrations inhibited generation of this TPA-induced band shift. These data suggest that TPA-induced growth inhibition is associated with phosphorylation of PU.1 and generation of a unique PU.1 binding activity.

Phorbol ester stimulated Cip1 expression in p53-negative leukemic cells.

In differentiating leukemic cells, cyclin-dependent kinase interacting protein (Cip1) is induced and stimulates a G(1) arrest. TPA treated U937 monoblastoid cells expressed Cip1, hypophosphorylated retinoblastoma protein (Rb), arrested in G(1) and differentiated. PKC-zeta cells are U937 cells that overexpress the zeta isoform and display alterations in endogenous PKC isoform expression. TPA treated PKC-zeta cells undergo apoptosis without differentiating. TPA treated PKC-zeta cells express Cip1 and display substantial hypophosphorylation of Rb but fail to arrest in G(1). Thus, a novel phorbol ester dependent signalling pathway exists in which Cip1 induction is associated with the absence of a G(1) arrest and induction of apoptosis rather than differentiation.

Phorbol esters induce death in MCF-7 breast cancer cells with altered expression of protein kinase C isoforms. Role for p53-independent induction of gadd-45 in initiating death.

Protein kinase C (PKC) modulates growth, differentiation and apoptosis in a cell-specific fashion. Overexpression of PKC-alpha in MCF-7 breast cancer cells (MCF-7-PKC-alpha cell) leads to expression of a more transformed phenotype. The response of MCF-7 and MCF-7-PKC-alpha cells to phorbol esters (TPA) was examined. TPA-treated MCF-7 cells demonstrated a modest cytostatic response associated with a G1 arrest that was accompanied by Cip1 expression and retinoblastoma hypophosphorylation. While p53 was detected in MCF-7 cells, evidence for TPA-induced stimulation of p53 transcriptional activity was not evident. In contrast, TPA treatment induced death of MCF-7-PKC-alpha cells. Bryostatin 1, another PKC activator, exerted modest cytostatic effects on MCF-7 cells while producing a cytotoxic response at low doses in MCF-7-PKC-alpha cells that waned at higher concentrations. TPA-treated MCF-7-PKC-alpha cells accumulated in G2/M, did not express p53, displayed decreased Cip1 expression, and demonstrated a reduction in retinoblastoma hypophosphorylation. TPA-treated MCF-7-PKC-alpha cells expressed gadd-45 which occurred before the onset of apoptosis. Thus, alterations in the PKC pathway can modulate the decision of a breast cancer cell to undergo death or differentiation. In addition, these data show that PKC activation can induce expression of gadd45 in a p53-independent fashion.

Phorbol ester treatment of U937 cells with altered protein kinase C content and distribution induces cell death rather than differentiation.

Overexpression of protein kinase C (PKC)-zeta, an atypical PKC isoform, in U937 cells stimulates certain parameters of phenotypic maturation and increases expression of endogenous alpha and beta PKC isoforms. In response to 12-O-tetradecanoylphorbol-13-acetate (TPA), parental U937 cells displayed growth arrest and differentiated into a monocyte/macrophage-like cell line, while PKC-zeta cells underwent death. The ability of GF109203X to inhibit TPA-induced death of PKC-zeta cells suggested that activation of a conventional isoform was necessary to induce apoptosis. While exhibiting unique morphological changes, parameters indicative of a further degree of differentiation were not observed in TPA-treated PKC-zeta cells. TPA-induced down-regulation of PKC activity was similar in both cells. While modest quantitative differences in individual isoform down-regulation existed, intracellular localization of isoforms prior to activation differed significantly between U937 and PKC-zeta cells. Expression of gadd45 was induced by TPA in PKC-zeta but not parental cells and occurred as a primary response to TPA and prior to the onset of cell death. These data suggest that the decision of a cell to undergo death or differentiation in response to phorbol esters may, in part, be modulated by alterations within the PKC signal transduction pathway.

MCF-7 breast cancer cells transfected with protein kinase C-alpha exhibit altered expression of other protein kinase C isoforms and display a more aggressive neoplastic phenotype.

Increased protein kinase C (PKC) activity in malignant breast tissue and positive correlations between PKC activity and expression of a more aggressive phenotype in breast cancer cell lines suggest a role for this signal transduction pathway in the pathogenesis and/or progression of breast cancer. To examine the role of PKC in the progression of breast cancer, human MCF-7 breast cancer cells were transfected with PKC-alpha, and a group of heterogenous cells stably overexpressing PKC-alpha were isolated (MCF-7-PKC-alpha). MCF-7-PKC-alpha cells expressed fivefold higher levels of PKC-alpha as compared to parental or vector-transfected MCF-7 cells. MCF-7-PKC-alpha cells also displayed a substantial increase in endogenous expression of PKC-beta and decreases in expression of the novel delta- and eta-PKC isoforms. MCF-7-PKC-alpha cells displayed an enhanced proliferative rate, anchorage-independent growth, dramatic morphologic alterations including loss of an epithelioid appearance, and increased tumorigenicity in nude mice. MCF-7-PKC-alpha cells exhibited a significant reduction in estrogen receptor expression and decreases in estrogen-dependent gene expression. These findings suggest that the PKC pathway may modulate progression of breast cancer to a more aggressive neoplastic process.

Cytogenetic and flow cytometric analysis of a pancreatoblastoma.

A pancreatoblastoma from a 4-year old male was examined by flow cytometric ploidy analysis and cytogenetics. To detect differences within the tumor, the specimen was divided into four portions and sampled separately. Flow analysis revealed that each sample contained a diploid and a tetraploid population of tumor cells. These findings correlated well with the cytogenetic analysis, which also revealed differences in structural rearrangements between samples. A t(13;22)(q10;q10) was the only rearrangement found in near-diploid cells as well as one near-tetraploid line. Other common structural changes in near-tetraploid cells included t(13;13)(q10;q10), i(6p)(p10), and del(1). Chromosomes 1, 6, 13, and 22 were consistently missing from all near-tetraploid cells lines. To our knowledge, this is the first flow cytometric and cytogenetic study of a pancreatoblastoma.

Overexpression of protein kinase C-zeta stimulates leukemic cell differentiation.

A function for protein kinase C-zeta (PKC-zeta), a member of the phorbol ester nonresponsive atypical protein kinase C subfamily, in modulating differentiation was examined in the leukemic U937 cell. Transfected U937 cells stably overexpressing PKC-zeta displayed a longer doubling time, lower saturation density at confluency, and an increase in adherence to plastic as compared to control cells. PKC-zeta cells expressed a more differentiated phenotype as assessed by changes in morphology, surface antigen expression, and lysosomal enzyme activities and were distinct from parental U937 cells stimulated to differentiate by exposure to phorbol esters. In contrast to parental U937 cells, PKC-zeta cells constitutively expressed mRNA transcripts for c-jun and a low mobility AP-1 binding activity. Thus, PKC-zeta overexpression stimulates a type of phenotypic differentiation that differs significantly from maturation occurring upon activation of other PKC subfamilies induced by phorbol ester treatment. Increased expression of the c-jun protooncogene and an increase in AP-1 binding activity in PKC-zeta cells provides a potential mechanism for explaining the altered differentiation status of this cell.