Stimulation of DNA synthesis by transient exposure of cell cultures to TPA or polypeptide mitogens: induction of competence or incomplete removal?

Evolutionary relationship between nonmammalian and mammalian peptides

An hypothesis has been developed to rationalize the evolution of regulatory peptides. In order to account for critical relationships involving peptide regulators, their receptors, and peptide processing enzymes, the following generalizations will be supported: (1) peptides arose from protein precursors as proteolytic digestion by-products and acquired hormonal status during the course of natural selection; (2) initially, peptides served primarily nutritional roles, thereby permitting increased growth rates and reproductive advantages for recipient cells; (3) specific peptide sequences were conserved during evolution and were associated with biological activities which were essential for survival of species as divergent as unicellular organisms, amphibians, and mammals; and (4) regulatory peptides probably arose simultaneously with their membrane-oriented, macromolecular receptor sites. In support of the conservation of sequence information or function, or both, during evolutionary development, evidence has been obtained to indicate that peptide sequences which occur in two classes of amphibian peptides appear to be extensively conserved in mammals. Studies with an antiserum directed against the N-terminal sequence of amphibian physalaemin have permitted the recognition of a mammalian octapeptide which exhibits 80% homology with residues 1-5 in that region. Another study with an antiserum directed against the midregion (sequence 5-8) of amphibian bombesin has indicated the existence of milk peptides which mimic bombesin in several pharmacological bioassays. These studies indicate that radioimmunoassays can be powerful tools in facilitating recognition of peptide sequences conserved throughout evolution.

The proliferative response of low-density human cell cultures to tumor promoters and its relevance to carcinogenic mechanisms in vitro

The effects of the tumor promoter -12-O-tetradecanoyl phorbol-13-acetate, its analogues, and other tumor promoters, on the proliferation of human skin fibroblasts (SF) have been investigated. We have previously shown (Kopelovich and Bias, 1979), that TPA caused a biphasic (upward concave) dose effect in the cloning efficiency assay of normal and mutant human fibroblastic cell strains. Here we report that the biphasic dose response pattern, consisting of an inhibitory phase and a stimulatory phase, was shared by the active analogues of TPA, e.g., phorbol-12,13-dibutyrate and phorbol-12,13-dibenzoate. This biphasic dose effect relationship, however, was not seen with phorbol-12,13-diacetate or the inactive analogues of TPA such as phorbol and 4-O-methyl-12-O-tetradecanoyl phorbol-13-acetate, nor was it seen with mezerein, teleocidin, or bile-acid derivatives of humans. An analysis of the cloning efficiency data by the median-effect equation (Chou and Talalay, 1981) showed that in low-density cultures both the inhibitory phase and the stimulatory phase of the dose-effect relationships of TPA, its analogues, mezerein, and teleocidin exhibited a linear median-effect plot and thus closely followed the basic mass-action principle. The median-effect plot of these data allowed quantitative determination of growth curve characteristic such as regression coefficient, slope (a measure of sigmoidicity), median-effect concentrations such as I50 for the inhibitory effect, and A50 for the stimulatory effect (i.e., the relative potency of the analogues) and the transition point of the biphasic phenomenon in the case of the phorbol esters. In addition, we have demonstrated a relationship between the dose response effect of TPA on the proliferation of various human cells and tumor progression in vitro.

Regulation of the rate of cell cycle progression in quiescent cytolytic T cells by T cell growth factor: analysis by flow microfluorometry

We have previously shown that greater than 90% of B6.1 cells, a murine cytolytic T lymphocyte (CTL) cloned line which is solely dependent on T cell growth factor (TCGF) for continuous growth in vitro, accumulates in the G1 phase of the cell cycle after transfer into culture medium containing no TCGF. Moreover, when such quiescent cells are exposed again to TCGF, greater than 85% reenter the S phase and subsequently divide in a relatively synchronous fashion. In this study, the regulation of the rate of cell cycle progression of quiescent B6.1 cells after exposure to TCGF was analyzed using two complementary DNA staining techniques, namely, the propodium iodide method (to enumerate cells entering the S phase) and the Hoechst 33342-bromodeoxyuridine substitution technique (to enumerate cells which have gone through mitosis). After TCGF addition, quiescent B6.1 cells resumed DNA synthesis and divided after a lag phase of 10 and 20 h, respectively. The duration of the lag phase was found to be dependent on the length of time during which quiescent B6.1 cells had been deprived of TCGF, but was independent of the concentration of TCGF used for restimulation. In contrast, the proportion of cells responding to TCGF as well as the rate of their first passage through mitosis was dependent on TCGF concentration. The presence of TCGF for at least 6 h was required for a maximal response. Moreover, direct evidence was obtained that TCGF by itself was able to stimulate proliferation of quiescent B6.1 cells in the absence of other growth factors and serum constituents other than bovine serum albumin, transferrin, and lipids.

Diacylglycerol stimulates DNA synthesis and cell division in mouse 3T3 cells: role of Ca2+-sensitive phospholipid-dependent protein kinase

The synthetic diacylglycerol 1-oleoyl-2-acetylglycerol competes directly with [3H]phorbol 12,13-dibutyrate for common binding sites in monolayer cultures of Swiss 3T3 cells and rapidly stimulates the phosphorylation of a Mr 80,000 cellular protein that has recently been shown to reflect the activation of protein kinase C in intact cells. Thus, this diacylglycerol provided a useful tool to determine whether exogenously added diacylglycerols can mimic the potent tumor promoter phorbol ester in eliciting DNA synthesis and cell division in quiescent cells. We found that OAG acts synergistically with insulin and other growth factors to stimulate reinitiation of cell proliferation, and several lines of evidence indicate that OAG shares with phorbol esters a common pathway of mitogenic action via stimulation of protein kinase C activity in intact 3T3 cells. The findings support the hypothesis that diacylglycerols represent endogenous analogs of phorbol esters and raise the possibility that diacylglycerols generated in the plasma membrane could act as a mitogenic signal for quiescent cells.

Reduction of epidermal growth factor receptor affinity by heterologous ligands: evidence for a mechanism involving the breakdown of phosphoinositides and the activation of protein kinase C

The tetradecapeptide bombesin converts epidermal growth factor (EGF) receptors on Swiss 3T3 cells from a high affinity state (KD = 9.8 X 10(-11)M) to a lower affinity state (KD = 1.8 X 10(-9)M). This conversion occurs when the cells are incubated with bombesin at 37 degrees C but not when incubated at 4 degrees C. Previously, a number of other (chemically unrelated) cell growth-promoting peptides and polypeptides have been shown to induce a similar indirect, temperature-dependent reduction of EGF receptor affinity. We have now demonstrated that hormones and growth factors which cross-regulate EGF receptor affinity in Swiss 3T3 cells have a common ability to stimulate the breakdown of phosphoinositides in these cells. We propose that the reduction of EGF receptor affinity is a consequence of the activation of protein kinase C by the diacylglycerol generated by this breakdown. In support of this proposal we have found that exogenously added diacylglycerol reduces the affinity of the Swiss 3T3 cell EGF receptor.

Augmentation of mixed lymphocyte response. Stimulatory activity by phorbol ester

The tumor promoter 12-O-tetradecanoylphorbol-13-acetate (TPA) induces a variety of phenotypic changes on normal and malignant cells. In chronic and acute lymphocytic leukemia we have observed a marked augmentation in mixed lymphocyte reaction stimulatory capacity (MLRs) following pretreatment of leukemia blasts with TPA. We have now characterized the effects of TPA on MLRs utilizing the non-T, non-B lymphoblastic leukemia-cell line, HOON. Following pretreatment with TPA (optimal concentration, 1.6 X 10(-10) M), but not with other phorbol esters, there was a marked increase in MLRs, particularly at lower stimulator-cell concentrations. This effect was maximal following a 44-hr preincubation period and the enhancement in MLRs was not accompanied by changes in levels of Ia expression. This cell line provides a model for determining the molecular basis for the TPA-induced augmentation of stimulatory capacity in the mixed lymphocyte reaction.

Insulin induces a selective heterologous desensitization of the mitogenic response of Swiss 3T3 cells to vasopressin

Prior incubation of confluent, quiescent cultures of Swiss 3T3 cells with insulin leads to a selective loss of mitogenic stimulation on re-addition of the combination of vasopressin and insulin in serum-free medium. The desensitization is specific for the action of vasopressin as insulin is fully active in the refractory cells when added in combination with other mitogens, whereas vasopressin is not. A prolonged treatment with insulin is required for induction of the refractoriness, half-maximal loss of response occurs after about 7 h and desensitization is complete after 12 h treatment. The refractory cells recover their response to vasopressin after more than 24 h incubation in the absence of insulin. A rapid response of the cells to vasopressin, inhibition of 125I-epidermal growth factor (125I-EGF) binding, is also desensitized by insulin. Desensitization is induced by insulin-like growth factor I (IGF-I), and partially by desoctapeptide insulin, but not by insulin B chain. Although the characteristics of insulin-induced desensitization are very similar to those of the homologous desensitization induced by vasopressin treatment, insulin does not bind to vasopressin antiserum or the [3H]vasopressin receptors of Swiss 3T3 cells. Insulin treatment also does not lead to any down-regulation of [3H]vasopressin receptors, and the refractoriness of the cells must therefore lie at a post-receptor step. Both insulin- and vasopressin-induced refractoriness to the mitogenic action of vasopressin can be blocked by a low level of cycloheximide. Both these agents therefore seem to induce the synthesis of specific protein(s) which selectively inhibit the mitogenic response of the cell to vasopressin.

Cell-specific regulation of the c-myc gene by lymphocyte mitogens and platelet-derived growth factor

We show that c-myc is an inducible gene that is regulated by specific growth signals in a cell-cycle-dependent manner. Specifically, agents that initiate the first phase of a proliferative response in lymphocytes (lipopolysaccharide or Concanavalin A) and fibroblasts (platelet-derived growth factor) induce c-myc mRNA. Within one to three hr after the addition of these mitogens to the appropriate cells, c-myc mRNA concentration is increased between 10- and 40-fold. This induction of c-myc mRNA occurs in the presence of cycloheximide and, therefore, does not require the synthesis of new protein species. Consequently, the induction of c-myc mRNA is not secondary to growth. In addition, c-myc mRNA is "superinduced" by the combination of cycloheximide and mitogen, a finding consistent with a model that a labile protein may regulate c-myc levels in these cells. Further, this work suggests a regulatory linkage between the function of two oncogenes--c-myc and c-sis--the latter being the putative structural gene for PDGF.

Molecular aspects of growth factor action: receptors and intracellular signals

An increasing number of factors have been described which influence the proliferative responses of normal and neoplastic cells. A review of such moieties, their occurrence and possible mechanisms of their action and interaction is presented together with a discussion of their potential importance in the genesis and progression of neoplasms.

A model of cell cycle control: sequential events regulated by growth factors

PDGF is a potent mitogen that initiates the proliferation of quiescent fibroblastic cells. EGF and somatomedin C (or insulin) can replace the requirement for plasma to function synergistically with PDGF to stimulate DNA synthesis. PDGF, EGF and somatomedin C control discrete cellular events in the cell cycle. Cyclic AMP can potentiate the effects of polypeptide mitogens. The down-regulation of EGF receptors by PDGF and cyclic AMP brings about a loss of the requirement for exogenous EGF. The transient treatment of density-arrested fibroblasts with PDGF allows better study of synergistic actions of PDGF and plasma-derived factors. These synergistic interactions are important to understand in determining how multiple growth factors regulate cellular proliferation.

Persistence of the mitogenic response to platelet-derived growth factor (competence) does not reflect a long-term interaction between the growth factor and the target cell

Quiescent BALB/c-3T3 cells exposed briefly to platelet-derived growth factor (PDGF) become "competent" to replicate their DNA even if PDGF is removed from cell culture medium prior to the onset of DNA synthesis. We have suggested that persistence of the PDGF-induced competent state reflects a rapidly induced and relatively stable biochemical change within the target cells. Others suggest that the phenomenon reflects a long-term association between PDGF and its target cells or perhaps between PDGF and the cell culture dish. This controversy has been addressed (a) by examining the effect of anti-PDGF antibodies on PDGF-induced competence and (b) by studying the chemical fate of 125I-labeled PDGF. Anti-PDGF antibodies inactive both soluble and surface-bound PDGF. However, if quiescent 3T3 cells are exposed to PDGF for as little as 30 min, subsequent addition of these antibodies to the culture medium does not prevent the mitogenic response. Under conditions where the PDGF-induced competent state decays stochastically with a t1/2 of 18-20 h, cell-associated 125I-PDGF decays with a t1/2 of approximately 50 min. These data do not support the concept that persistence of the PDGF-induced competent state reflects a long-term association between PDGF and the target cells or between PDGF and the culture dish.

Vasopressin induces selective desensitization of its mitogenic response in Swiss 3T3 cells

Prior incubation of quiescent cultures of Swiss 3T3 cells with vasopressin leads to loss of mitogenic stimulation on its subsequent addition in the presence of a synergistic growth factor. This desensitization is selective for vasopressin, requires prolonged incubation (half-maximal desensitization after 12 hr of treatment) for its induction, and is reversed after a 48-hr incubation in the absence of vasopressin. It is elicited by concentrations of vasopressin, and several analogues, similar to those required for stimulation of DNA synthesis. Inhibition of 125I-labeled epidermal growth factor binding and stimulation of 86Rb+ uptake by vasopressin are also selectively decreased in the refractory cells. The vasopressin receptors that mediate mitogenesis in Swiss 3T3 cells are of the pressor type, not coupled to adenylate cyclase. These cells bind [3H]vasopressin in a specific and saturable (Kd = 1 X 10(-8) M) manner. The receptors are down-regulated after prolonged vasopressin treatment; however, this cannot provide a complete explanation of desensitization because cells that are completely refractory to vasopressin retain 60% of their [3H]vasopressin binding sites. Vasopressin refractoriness must therefore occur partly at a post-receptor locus.

Tumor promoter 12-O-tetradecanoylphorbol 13-acetate, like epidermal growth factor, stimulates cell proliferation and inhibits differentiation of mouse mammary epithelial cells in culture

12-O-Tetradecanoylphorbol 13-acetate (TPA) is a potent tumor promoter and shares several biological activities of epidermal growth factor (EGF). Recently we have shown that EGF stimulates DNA synthesis and inhibits milk protein synthesis induced by insulin, cortisol, and prolactin in a primary mouse mammary epithelial cell culture [Taketani, Y. & Oka, T. (1983) FEBS Lett., in press]. Using this system, we examined the biological action of TPA in reference to that of EGF. TPA stimulated cell proliferation and inhibited the synthesis of milk proteins casein and alpha-lactalbumin during a 5-day culture. The ED50 was about 2.5 ng/ml for DNA synthesis and 0.1 ng/ml for milk protein synthesis. Removal of TPA from the medium normalized DNA synthesis completely and casein synthesis partially. The ability of various TPA analogs to stimulate DNA synthesis and inhibit casein synthesis correlated with their potency as tumor promoters. Both TPA and EGF decreased the specific prolactin binding of cultured cells by approximately equal to 50%. These results indicate that TPA, like EGF, switches the developmental course of mammary epithelium from differentiation to proliferation.

Calcium ions and the control of proliferation in normal and cancer cells

Several lines of evidence suggest tha Ca2+ ions control cell proliferation: Ca2+ entry into cytoplasm acts as a general mitogen; serum and serum-replacements induce Ca2+ influx; the Ca2+ concentrations in growth media required to support the proliferation of normal cells are much higher than those required for cancer cells; serum and growth factors reduce the Ca2+ requirements of normal cells; tumour promoters alter Ca2+ fluxes via a mechanism used principally by growth factors. Minor supporting evidence includes the effects of various drugs and viruses, and the behaviour of tumour cell mitochondria and intercellular junctions. It is still not possible to decide exactly where and when inside cells the critical effect of Ca2+ on proliferation occurs, but we discuss at length the practical problems of understanding Ca2+ movements in tissue-culture cells. Carried to its logical conclusion, present evidence suggests that an overridden or bypassed Ca2+ control process may be the key, common determinant of unrestrained proliferation in cancer cells.