In vivo and in vitro phosphorylation studies of numatrin, a cell cycle regulated nuclear protein, in insulin-stimulated NIH 3T3 HIR cells

Numatrin, a nuclear matrix protein has been implicated to be involved in mitogenesis of normal and malignant cells (Feuerstein and Mond, J. Biol. Chem. 262, 11389, 1987) and was later found to be identical to the nuclear phosphoprotein, B23. To study whether phosphorylation of numatrin is regulated by mitogenic stimulation, we examined the effect of phosphorylation of numatrin in the insulin-responsive cells, NIH 3T3 HIR. We found that an increase in phosphorylation of numatrin was associated with stimulation of the cells with insulin for 4 h and that the level of phosphorylation remained elevated after 8 h. By this time there was no increase in numatrin abundance as shown by Coom-massie blue stain and Western blot analysis. The induction in phosphorylation of numatrin could not be detected after 30 min stimulation with insulin, thus, indicating that the increase in phosphorylation of numatrin is not a rapid event. Analysis of the phosphopeptides by thin layer chromatography indicated four peptides that were phosphorylated in numatrin (one major and three minor). Stimulation with insulin was associated primarily with an increase in phosphorylation of the minor phosphopeptides. The phosphopeptide map of numatrin was identical after 4, 8, 17, 24, and 32 h stimulation with insulin, indicating that identical sites are phosphorylated at different phases of the cell cycle. In a search for the protein kinase which is involved in phosphorylation of numatrin we found that numatrin is a most prominent substrate for the cell cycle regulated cdc2 (p 34) kinase. However, the major phosphopeptides which were phosphorylated by this kinase did not comigrate with either of the phosphopeptides phosphorylated in insulin-stimulated intact cells. This may indicate that it is unlikely that cdc2 kinase may account for the mechanism(s) associated with phosphorylation of numatrin by insulin under physiological conditions.     

"Numatrin," a nuclear matrix protein associated with induction of proliferation in B lymphocytes

To detect nuclear proteins that might be involved in induction of cellular mitogenesis, we examined the effect of various mitogens on early changes in synthesis of nuclear proteins in murine B lymphocytes. Using two-dimensional gel electrophoresis, we found that activation of B cells by mitogens (anti-immunoglobulin antibody, lipopolysaccharide, phorbol 12-myristate 13-acetate (PMA)/A23187) was associated with a rapid and prominent (5-20-fold) increase in the synthesis of a 40-kDa/pI 5.0 nuclear protein, here termed numatrin. Numatrin was found to be absent from the cytosol (soluble fraction) of resting as well as activated B cells and was markedly resistant to DNase/RNase digestion and 2 N NaCl extraction, indicating that this protein is tightly bound to the nuclear matrix. Kinetic studies showed that the increase in synthesis of numatrin was detected 60-120 min following mitogen activation, reached a peak at 16 h, and declined to almost control level by 48 h, correlating with the peak of cellular DNA synthesis. The increase in synthesis of numatrin in normal B cells was found to be associated exclusively with cellular commitment for mitogenesis because activation of B cells by stimuli such as B cell stimulating factor 1, PMA alone, and calcium ionophore A23187, which do not stimulate an increase in DNA synthesis, also failed to induce an increase in the synthesis of numatrin. Inhibition of anti-Ig-induced proliferation (by PMA pretreatment) was associated with a 63% inhibition in the synthesis of numatrin. Addition of 8-mercaptoguanosine to these PMA-treated cells was associated with restoration of the increase in synthesis of numatrin, concomitant with induction of proliferation. Elevated synthesis of numatrin was also detected in the malignant B lymphoma cells: Raji, BAL-17, and WEHI-231. Taken collectively, these results suggest that numatrin, a tightly bound nuclear matrix protein, is a growth-regulated protein which might have an important role in regulation of cellular mitogenesis in normal and malignant B lymphocytes.     

In vivo and in vitro phosphorylation studies of numatrin, a cell cycle regulated nuclear protein, in insulin-stimulated NIH 3T3 HIR cells

Numatrin, a nuclear matrix protein has been implicated to be involved in mitogenesis of normal and malignant cells (Feuerstein and Mond, J. Biol. Chem. 262, 11389, 1987) and was later found to be identical to the nuclear phosphoprotein, B23. To study whether phosphorylation of numatrin is regulated by mitogenic stimulation, we examined the effect of phosphorylation of numatrin in the insulin-responsive cells, NIH 3T3 HIR. We found that an increase in phosphorylation of numatrin was associated with stimulation of the cells with insulin for 4 h and that the level of phosphorylation remained elevated after 8 h. By this time there was no increase in numatrin abundance as shown by Coommassie blue stain and Western blot analysis. The induction in phosphorylation of numatrin could not be detected after 30 min stimulation with insulin, thus, indicating that the increase in phosphorylation of numatrin is not a rapid event. Analysis of the phosphopeptides by thin layer chromatography indicated four peptides that were phosphorylated in numatrin (one major and three minor). Stimulation with insulin was associated primarily with an increase in phosphorylation of the minor phosphopeptides. The phosphopeptide map of numatrin was identical after 4, 8, 17, 24, and 32 h stimulation with insulin, indicating that identical sites are phosphorylated at different phases of the cell cycle. In a search for the protein kinase which is involved in phosphorylation of numatrin we found that numatrin is a most prominent substrate for the cell cycle regulated cdc2 (p 34) kinase. However, the major phosphopeptides which were phosphorylated by this kinase did not comigrate with either of the phosphopeptides phosphorylated in insulin-stimulated intact cells. This may indicate that it is unlikely that cdc2 kinase may account for the mechanism(s) associated with phosphorylation of numatrin by insulin under physiological conditions.     

Identification of a prominent nuclear protein associated with proliferation of normal and malignant B cells

Experiments were undertaken to identify nuclear proteins that might be involved in regulation of the mitogenic process in B lymphocytes. Murine splenic B lymphocytes were purified and cultured with anti-Ig insolubilized onto Sepharose (anti-Ig/Sepharose) for 16 hr and labeled with [35S]methionine. Nuclei were isolated and the nuclear proteins were analyzed by two-dimensional gel electrophoresis. Anti-Ig/Sepharose induced a prominent increase in the synthesis and abundance of a 40 kDa/pI 5 nuclear protein (p40/pI-5). Inhibition of anti-Ig/Sepharose-induced mitogenesis by pretreatment of the cells with phorbol-12-myristate-13-acetate was associated with a specific inhibition (63%) of p40/pI-5. Subcellular fractionation experiments showed that p40/pI-5 is not detected in the soluble fraction of resting or activated B cells, indicating that this protein is located exclusively in the nucleus. Analysis of the expression of p40/pI-5 relative the cell cycle showed that the synthesis of this protein was increased during G1 phase and gradually reduced during S phase of the cell cycle. Abundant amounts of p40/pI-5 were also found in the rapidly proliferating B lymphoma cells, WEHI-231, and growth arrest of these cells by anti-mu was found to be associated with a marked inhibition (68%) of this protein. Taken collectively these results suggest that the nuclear protein p40/pI-5 may have an important role in regulation of the proliferation of normal and malignant B lymphocytes.     

Phosphorylation of numatrin and other nuclear proteins by cdc2 containing CTD kinase cdc2/p58

Numatrin is a nuclear matrix phosphoprotein whose synthesis and abundance were shown to be regulated during the cell cycle in mitogen-stimulated lymphocytes (Feuerstein, N., and Mond, J. (1987) J. Biol. Chem. 262, 11389-11397). We examined the effect of (a) CTD-kinase, which contains the cdc2 catalytic component (p34) in a complex with a p58 subunit (cdc2/p58) and (b) the M phase-specific histone H1 kinase, which contains the cdc2 kinase in association with a p62 subunit (cdc2/p62), on phosphorylation of numatrin. We show that both cdc2 kinase complexes can phosphorylate numatrin. However, cdc2/p58 at conditions that caused a similar effect to cdc2/p62 on phosphorylation of histone H1 (dpm/micrograms of substrate/micrograms of enzyme) was found to have a 5-25-fold higher catalytic activity in the phosphorylation of numatrin. Analysis of the tryptic phosphopeptide map of numatrin phosphorylated by these cdc2 kinase complexes showed that both kinase complexes phosphorylated two major identical peptides, but minor additional peptides were differentially phosphorylated by each of these kinases. This indicates that under certain experimental conditions cdc2/p58 and cdc2/p62 may express some differences in their catalytic activity. In vitro phosphorylation by CTD kinase of a whole nuclear protein extract from murine fibroblasts showed that numatrin is the most prominent substrate for CTD kinase in this nuclear extract. CTD kinase cdc2/p58 was found to induce significantly the phosphorylation of five other discrete nuclear substrates. Particularly, two nuclear proteins at 75 kDa/pI approximately 6.5 and 85 kDa/pI approximately 5.3, which were not Coomassie Blue stainable, were found to be markedly phosphorylated by CTD kinase. The results of this study call for further study of the role of CTD kinase cdc2/p58 in the phosphorylation of numatrin under physiological conditions and to further characterization of the other nuclear substrates for CTD kinase.     

Identification of numatrin, the nuclear matrix protein associated with induction of mitogenesis, as the nucleolar protein B23. Implication for the role of the nucleolus in early transduction of mitogenic signals

We have previously described and characterized a nuclear protein at 40 kDa/pI 5 termed "numatrin" which is tightly bound to the nuclear matrix. We demonstrated that a rapid increase in the synthesis of numatrin at early G1 phase is closely correlated with receptor-mediated induction of cellular proliferation by various mitogens and that elevated amounts of numatrin are found in tumor cells, suggesting that numatrin may have an important role in regulation of cellular growth in normal and malignant cells. Further experiments were undertaken to compare the biochemical characteristics of numatrin to those of other known proteins that are associated with cellular mitogenesis. Comparison of the electrophoretic mobility of numatrin with the proliferation cell nuclear antigen/cyclin showed that these proteins are not identical. However, numatrin had an identical electrophoretic migration on two-dimensional gel electrophoresis to that of a previously described nucleolar protein B23. The tryptic digest peptide map of 125I-labeled B23 was identical to that of numatrin on two-dimensional thin layer electrophoresis/chromatography. Labeling of cells with 32P further showed that numatrin is a major phosphoprotein as previously reported for protein B23. Using the protocol for purification of B23, we purified numatrin from nucleoli of HL-60 cells and produced two polyclonal antibodies (303 and 339) to this protein. We further show that numatrin is recognized by anti-B23 monoclonal antibody as well as by polyclonal antibodies 303 and 339 in enzyme-linked immunosorbent assay. Conversely, these anti-numatrin polyclonal antibodies cross-react with protein B23 as shown in immunoblot analysis. These results, taken collectively, prove that numatrin is identical to the nucleolar protein B23 and thus suggest that protein B23 and events which occur at the nucleolus might have an important role in early transduction of mitogenic signals at the G1 phase of the cell cycle.     

The T11 (CD2) molecule is functionally linked to the T3/Ti T cell receptor in the majority of T cells

Most mature human T lymphocytes express both the multichain T3 (CD3)/Ti T cell receptor for antigen (TCR), and the biochemically distinct 55-kDa T11 (CD2) glycoprotein. Stimulating the T11 molecule causes profound T cell proliferation and functional activation in vitro, but the relationship of T11-mediated activation to antigenic stimulation of T lymphocytes in vivo remains unknown. We now present evidence that T11 function is directly linked to TCR components in T3/Ti+ T11+ human T cells. First, we found that stimulating peripheral blood T cells with the mitogenic combination of anti-T11(2) cells with the mitogenic combination of anti-T11(2) plus anti-T11(3) monoclonal antibodies caused the phosphorylation of TCR T3 chains. The predominance of T3-gamma-phosphorylation that occurred in anti-T11(2) plus anti-T11(3)-treated T cells is similar to the pattern previously observed in antigen-stimulated T cell clones. Second, T11 function depended upon concurrent cell-surface expression of the TCR. Thus, when peripheral blood T cells were deprived of cell surface T3/Ti by anti-T3 modulation, anti-T11(2) plus anti-T11(3)-induced mitogenesis and transmembrane signal generation in the form of calcium mobilization were inhibited. The mechanism of TCR-T11 interdependence was investigated in a series of TCR-deficient variants of a T cell lymphoblastoid cell line. T3/Ti negative variants expressed cell surface T11, but anti-T11(2) plus anti-T11(3) failed to cause detectable calcium mobilization. The TCR-deficient variants also failed to express T11(3) activation epitopes after incubation with anti-T11(2) antibodies, suggesting that T11(3) expression is an essential and TCR-dependent intermediate in the T11 activation mechanism in these cells. Taken together, our results suggest that T11 function depends upon cell-surface expression of TCR in many T3/Ti+ T11+ T lymphocytes, and T11-mediated activation is intimately interconnected with TCR activation mechanisms. A model in which stimulating signals delivered via T11 may be a part of antigenic activation of T lymphocytes is presented.     

Cross-linking of T3 (CD3) with T4 (CD4) enhances the proliferation of resting T lymphocytes

Monoclonal antibodies reactive with defined T lymphocyte surface antigens were covalently coupled to protein A-Sepharose beads using the bifunctional imidoester, dimethyl pimelimidate. Sepharose-immobilized antibody reactive with T3 induced the proliferation of resting T lymphocytes in the presence of either recombinant interleukin 2 or phorbol myristate acetate. When monoclonal antibodies reactive with T3 and T4 were coupled to the same Sepharose bead (hereafter designated Sepharose (T3:T4)), proliferation was enhanced an average of three-fold. Similarly prepared Sepharose beads coupled to anti-T3 and anti-T8 also enhanced proliferation over that observed with anti-T3 alone. Sepharose (T3:T4) similarly increased the proliferation of T4+ lymphocytes and a T4+ clone but failed to enhance the proliferation of T8+ lymphocytes. The increased proliferation of T4+ lymphocytes resulted from a preferential activation of the T4+2H4- helper population over the T4+2H4+ suppressor-inducer population. The enhanced proliferation induced by Sepharose (T3:T4) could be completely inhibited by soluble anti-T4. These results suggest that perturbation of T3 may be a minimal signal for T cell activation and that the assembly of a multimeric complex including T3 and T4 may be required for optimal T cell activation.     

A 12-O-tetradecanoylphorbol-13-acetate (TPA)-nonproliferative variant of 3T3 cells is resistant to TPA-enhanced gene amplification.

Barsoum and Varshavsky (Proc. Natl. Acad. Sci. U.S.A. 80:5330-5334, 1983) suggest that polypeptide mitogens and the mitogenic tumor promoter 12-O-tetradecanoylphorbol-13-acetate (TPA) stimulate gene amplification by related pathways. I demonstrated that TPA and the polypeptide mitogen fibroblast growth factor (FGF) both increase the frequency of cadmium-resistant variants of Swiss-Webster 3T3 cells. The molecular basis for this phenomenon is the amplification of the metallothionein gene(s). To further characterize the relationship between mitogenesis and gene amplification, I examined the ability of TPA and FGF to increase the frequency of cadmium-resistant colonies in the 3T3 variant cell line 3T3-TNR9. Unlike 3T3 cells, 3T3-TNR9 cells cannot be stimulated by TPA to divide (E. Butler-Gralla and H. R. Herschman, J. Cell. Physiol. 107:59-68, 1981). TPA does not induce an increase in cadmium-resistant colonies of the TPA-nonproliferative 3T3-TNR9, variant, in contrast to its efficacy on 3T3 cells. FGF, a potent mitogen for 3T3-TNR9 cells as well as 3T3 cells, is equally effective for 3T3-TNR9 and 3T3 cells in inducing cadmium-resistant colonies. These data suggest that the pathways of TPA-induced gene amplification and TPA-stimulated mitogenesis share a common step(s). TPA caused transient inhibition of DNA synthesis in both dividing 3T3 and 3T3-TNR9 cells, suggesting that this latter response to TPA is not sufficient to enhance gene amplification.     

Stimulation of mitogenesis and glucose transport by 1-monooleoylglycerol in Swiss 3T3 fibroblasts

1-Monooleoylglycerol (MOG), a recently reported diacylglycerol kinase inhibitor (Bishop, W. R., Ganong, B. R., and Bell, R. M. (1986) J. Biol. Chem. 261, 6993-7000), exerts potent stimulatory effects on [3H]thymidine incorporation into DNA and glucose transport in Swiss 3T3 fibroblasts. MOG induces a rapid and sustained 2.5-fold increase in the cellular 1,2-diacylglycerol (1,2-DG) content, and phosphorylation of an acidic 80-kDa protein, a putative substrate for the protein kinase C (Ca2+/phospholipid-dependent protein kinase). The effect of MOG is additive to that of bombesin in terms of both an increase in tissue diacylglycerol content and phosphorylation of the 80-kDa proteins. In addition to these effects, MOG potently stimulates release of arachidonic acid from phospholipids. Inhibitors of cyclooxygenase and lipoxygenase have little effect, if any, on MOG-induced stimulation of glucose transport and DNA synthesis, while exogenously applied arachidonic readily stimulates both of these cellular responses. Furthermore, arachidonic acid, at its biologically active concentrations, is found to induce a rapid and sustained increase in cellular 1,2-DG content and stimulate the phosphorylation of the 80-kDa protein, although to a lesser extent than MOG. Prolonged pretreatment of the cells with phorbol 12,13-dibutyrate, which reduces the cellular protein kinase C content, markedly attenuates the effects of both MOG and arachidonic acid on glucose transport and DNA synthesis. These data indicate that MOG increases endogenous 1,2-DG content and thereby acts as a potent activator of protein kinase C, and that activation of protein kinase C is a crucial step in MOG-induced stimulation of mitogenesis and glucose transport.     

Heterogeneity of human T4+ inducer T cells defined by a monoclonal antibody that delineates two functional subpopulations

A monoclonal antibody termed anti-T4 that detected approximately 60% of peripheral blood T lymphocytes was shown to define the human inducer population. In the present study, we characterized three additional monoclonal antibodies, anti-T4A, anti-T4B, and anti-TQ1, that were reactive with a similar percentage of T lymphocytes. Anti-T4A, anti-T4B, and anti-T4 delineated identical cell populations, while those defined by anti-TQ1 differed in several respects: 1) Anti-TQ1 stained a minority (less than 7%) of thymocytes, whereas the other antibodies stained a majority (80%); 2) Anti-TQ1 reacted with 70 to 85% of T4+ lymphocytes, but also stained 50% of T cells within the T4- (T8+) cytotoxic/suppressor subset; 3) The antigen defined by anti-TQ1 was not restricted in its expression to T cells; it defined a fraction of normal B and null lymphocytes as well as non-T cell lines. In vitro studies indicated that the subpopulations of T4+ T lymphocytes delineated by anti-TQ1 were functionally distinct. Although T4+TQ1+ and T4+TQ1- T cells proliferated in an equal fashion to soluble antigen and alloantigen, only the T4+TQ1+ subset was responsible for maximal proliferation in autologous MLR. This T4+TQ1+ subset contained a population of lymphocytes reactive with the previously defined JRA autoantibody. In contrast, the T4+TQ1-, but not the T4+TQ1+, subset provided the majority of T cell help for B cell immunoglobulin production in a pokeweed-driven system. We conclude that the subpopulation of T4+ inducer cells responsible for maximal helper activity in T-B interactions is restricted to a minor subpopulation of T4+ lymphocytes.     

Physical and functional association of the T cell receptor and the T3 molecular complex on cytotoxic T cell clones that are differentially inhibitable by anti-T3 antibodies

To examine the hypothesis that the antigen-specific T cell receptor (TcR) can function independently from the T3 complex on cytolytic T lymphocyte (CTL) clones, the physical and functional association of the T3 molecular complex and the T cell receptor has been examined on CTL clones that are differentially susceptible to inhibition by anti-T3 antibodies. From a panel of nine DPw2-specific CTL clones derived from the same donor, two clones (8.4 and 8.8) that were the most disparate in their susceptibility to inhibition by anti-T3 antibody were chosen for study. No significant differences were found between 8.4 and 8.8 for: (1) the levels of cell surface expression of the T3 complex and the TcR; (2) the ability to modulate T3 cell surface molecules; and (3) the capacity of the TcR to comodulate with the T3 complex. Modulation of the T3 complex from clone 8.4 did not significantly affect cytolytic activity, and incubation of modulated 8.4 with additional anti-T3 antibody did not inhibit cytolytic activity. Although no T3 function for clone 8.4 could be demonstrated by simply blocking cytolytic activity with anti-T3 antibody, addition of limiting quantities of anti-T11 (but not anti-T4, anti-Tac, or anti-LFA-1) antibodies plus anti-T3 produced a marked synergistic inhibition of cytolysis. These results suggest that: (1) CTL clones that are resistant to inhibition by anti-T3 antibodies actually have a physical and functional association between the T3 complex and the TcR; and (2) the ability to demonstrate a functional role for T3 by antibody blocking may, in some cases, require limiting the involvement of the T11 molecule in CTL-target interactions. The most likely explanation for the observed heterogeneity in susceptibility to blocking by anti-T3 antibodies is, therefore, thought to be that individual CTL clones possess TcR with differential avidity for specific targets.     

The T3/T cell receptor complex: antigenic distinction between the two 20-kd T3 (T3-delta and T3-epsilon) subunits.

Clonally distributed (clonotypic) antigen receptors on human T lymphocytes (alpha and beta chains) are associated with three invariable T3 polypeptide chains (T3 gamma, delta and epsilon), together forming the T3/T cell receptor complex. Monoclonal antibodies prepared against the two 20-kd T3 polypeptide chains demonstrated that T3-delta and T3-epsilon are distinct polypeptide chains. Only one monoclonal antibody (anti-T3-delta chain) reacted with the T cell surface as judged by indirect immunofluorescence, and by its mitogenicity for quiescent peripheral blood lymphocytes. Immunohistological staining and immunoprecipitation experiments showed that both the T3-delta and T3-epsilon chains are T cell-specific. As seen with the anti-alpha/beta chain reagent WT-31, anti-T3-delta chain monoclonal antibodies stained medullary thymocytes more intensely than cortical thymocytes, whereas the difference between the staining of cortical and medullary thymocytes was generally not apparent with anti-T3-epsilon chain antibodies. Because of this specificity and their ability to react with both the denatured and the native forms of each polypeptide chain, these new monoclonal reagents will be useful tools in studies of the biosynthesis and cell surface expression of the T3/T cell receptor complex during normal and malignant thymic differentiation.     

Transformation of BALB/3T3 cells by simian virus 40 causes a decreased synthesis of a collagen-binding heat-shock protein (hsp47)

The synthesis of a major collagen-binding heat-shock protein of molecular weight 47,000 (hsp47) was shown previously to be decreased after transformation of chick embryo fibroblasts by Rous sarcoma virus (Nagata, K., and Yamada, K. M. (1986) J. Biol. Chem. 261, 7531-7536; and Nagata, K., Saga, S., and Yamada, K. M. (1986) J. Cell Biol. 103, 223-229). In this paper, further study demonstrated that the total amount and the synthesis of hsp47 are also decreased by a factor of three in BALB/3T3 cells transformed by simian virus 40 (SV40). Higher synthesis was observed for BALB/3T3 cells in the resting state compared to those in the proliferating state. The synthesis of hsp47 in SV40-transformed cells, however, was consistently lower than that in normal cells irrespective of the cell density. Pulse label and chase experiments revealed that hsp47 was stable in the cells for at least 6 h and that there was no difference between normal and transformed BALB/3T3 cells in terms of the half-life. Decreases in the amount and the synthesis of hsp47 by transformation apparently correlate with the decreased synthesis of collagen in transformed cells. Immunoprecipitation using rat monoclonal antibody against hsp47 demonstrated the association of hsp47 with intracellular procollagen. Immunofluorescence studies using anti-hsp47 monoclonal antibody and anti-collagen antibody confirmed the co-localization of hsp47 and procollagen in both nonshocked and heat-shocked cells. Furthermore, we determined the biochemical characteristics of hsp47 of heat-shocked cells.     

Characterization of a monoclonal antibody to guinea pig T cells that inhibits rosette formation of the cells with rabbit erythrocytes: similarity of the antigen to E-receptor on human T cells

A monoclonal antibody, GPT-1, was prepared by fusion of the splenic cells of mice immunized with guinea pig thymocytes with a mouse myeloma cell line. GPT-1 completely inhibited spontaneous rosette formation of T cells with papain-treated rabbit erythrocytes. GPT-1 reacted with 90% of thymocytes, 70% of peripheral blood lymphocytes, and 45% of splenic lymphocytes, but not with B cells. These results indicate that GPT-1 has pan-T reactivity. The antibody specifically bound to a single polypeptide chain with a molecular size of 50-65 kD. The surface density of the antigen was higher on thymocytes than on peripheral T cells, suggesting that the antigen is a certain differentiation antigen on T cells. Phytohemagglutinin-activated T cells expressed more antigen molecules than resting T cells. In addition, GPT-1 suppressed the proliferation of T cells induced by the mitogen, indicating that GPT-1 recognizes a T cell-specific surface antigen which is associated with T cell activation. Based on these results, it was concluded that GPT-1 reacts with a guinea pig T cell surface antigen which is similar to the E-receptor protein on human T cells (CD2 molecule).     

A novel vasoactive peptide endothelin stimulates mitogenesis through inositol lipid turnover in Swiss 3T3 fibroblasts

Endothelin, a novel vasoactive peptide derived from endothelial cells (Yanagisawa, M., Kurihara, H., Kimura, S., Tomobe, Y., Kobayashi, M., Mitsui, Y., Yazaki, Y., Goto, K., and Masaki, T. (1988) Nature 332, 411-415), acts as a potent mitogen in Swiss 3T3 fibroblasts. The effect is dose-dependent with a half-maximal effect obtained at approximately 3 x 10(-11) M and is synergistically enhanced by a low concentration of insulin-like growth factor-I. Endothelin specifically binds to a single class of high affinity receptors in intact Swiss 3T3 cells and stimulates phospholipase C with the production of second messengers inositol trisphosphate and 1,2-diacylglycerol, leading to biphasic increases in the intracellular free Ca2+ concentration, as measured with a fluorescent indicator fura-2, phosphorylation of a putative cellular substrate of 80 kDa for protein kinase C, and transient expression of cellular protoonocogenes, c-fos and c-myc. Mitogenic effect of endothelin is markedly attenuated in phorbol ester-pretreated, protein kinase C-depleted cells. Endothelin-induced inositol phosphates production is not affected by removal of extracellular Ca2+, suggesting that endothelin-induced phospholipase C activation is not the result of stimulation of Ca2+ influx across the plasma membrane. These composite results indicate that the inositol lipid signaling pathway plays an important role in endothelin-induced mitogenesis in Swiss 3T3 fibroblasts. The mitogenic effect of endothelin is considerably smaller than that of bombesin, another well characterized mitogen acting through the inositol lipid pathway, despite comparable potencies in eliciting initial second messenger signals. In endothelin-treated cells, an increase in cellular 1,2-diacylglycerol content is transient, and cellular cyclic AMP content is reduced. By contrast, bombesin induces a more prolonged increase in cellular 1,2-diacylglycerol content and a slight increase in cellular cyclic AMP content. Because both 1,2-diacylglycerol and cyclic AMP are thought to serve as signals for promoting DNA synthesis in Swiss 3T3 fibroblasts, these differences in the signal generation may contribute to the differences in potencies between the two mitogens.     

Antigen recognition by human T lymphocytes is linked to surface expression of the T3 molecular complex

Four distinct surface molecules on human T cells are defined by the monoclonal antibodies anti-T1, anti-T3 (anti-T3_A), anti-T11 and anti-T12. Following cell binding, anti-T3 (anti-T3_A) and anti-T1 induce independent modulation of their respective ligands, whereas anti-T11 and anti-T12 do not. To explore the biological consequences of this modulation, we used cloned populations of T4 and T8 cytotoxic T lymphocytes. Anti-T3 (anti-T3_A), but not anti-T1, inhibits cytotoxic T lymphocyte effector function by T4 and T8 clones as well as antigen-specific T cell recognition. The latter is not secondary to a generalized inhibitory effect since responsiveness to interleukin 2 is maintained. Moreover, after modulation, cytotoxic T lymphocytes recover cytolytic function in parallel with reexpression of surface T3 molecules. We provide evidence for a direct linkage between antigen recognition by T lymphocytes and surface expression of the T3 molecular complex.     

Bombesin induction of c-fos and c-myc proto-oncogenes in Swiss 3T3 cells: significance for the mitogenic response

Bombesin is a potent mitogen for Swiss 3T3 cells and acts synergistically with insulin and other growth factors. We show here that addition of bombesin to quiescent Swiss 3T3 cells causes a striking increase in the levels of c-fos and c-myc mRNAs. Enhanced expression of c-fos (122 +/- 14-fold) occurred within minutes of peptide addition followed by increased expression of c-myc (82 +/- 16-fold). The concentrations of peptide required for half-maximal increase in the levels of c-fos and c-myc mRNAs were 1.0 and 0.9 nM, respectively. The peptide [D-Arg1, D-Pro2, D-Trp7,9, Leu11] substance P which inhibits the binding of bombesin to its receptor and bombesin-stimulated DNA synthesis in Swiss 3T3 cells blocked the increase in c-fos and c-myc mRNA levels promoted by bombesin. Down-regulation of protein kinase C by long-term exposure to phorbol esters prevented c-fos and c-myc induction by bombesin. This and other results indicate that the induction of these proto-oncogenes by bombesin could be mediated by the coordinated effects of protein kinase C activation and Ca2+ mobilization. The marked synergistic effect between bombesin and insulin was used to assess whether the increase in the induction of c-fos and c-myc is an obligatory event in cell activation. In the presence of insulin, bombesin stimulated DNA synthesis at subnanomolar concentrations but had only a small effect on c-fos and c-myc mRNA levels. This apparent dissociation of mitogenesis from proto-oncogene induction was even more dramatic in 3T3 cells with down-regulated protein kinase C. In these cells bombesin stimulated DNA synthesis in the presence of insulin but failed to enhance c-fos and c-myc mRNA levels at comparable concentrations. Thus, the induction of c-fos and c-myc may be a necessary step in the mitogenic response initiated by ligands that act through activation of protein kinase C but the expression of these proto-oncogenes may not be an obligatory event in the stimulation of mitogenesis in 3T3 cells by mitogens that utilise other signalling pathways.     

Proliferation of phenotypically immature human thymocytes with and without interleukin 2 receptors

Previous studies have indicated that the human thymus is composed of several discrete compartments. Cortical thymocytes are reactive with the monoclonal antibody anti-T6, whereas most medullary cells, unreactive with anti-T6, stain brightly with anti-T3, which defines mature T cell populations. Only a minor thymocyte population lacks both T3 and T6 but expresses T11 antigens. Within the thymus, several proliferating lymphoblasts are present. In addition a distinct subset shows the capacity to proliferate in response to mitogens. By continuous Percoll density gradient centrifugation, we have obtained a cell fraction comprising the vast majority of cells able to proliferate spontaneously or after PHA stimulation. By a panning procedure performed with anti-T3 and anti-T6 antibodies, three phenotypically distinct thymocyte subsets were separated from this fraction, and their functional capabilities were tested. The spontaneous proliferating activity was found to be mainly attributable to thymocytes unable to respond to mitogen, expressing the cortical T6 marker and lacking receptors for IL 2. T3-positive cells are able to respond to mitogen. However, these thymocytes are incapable of producing the adequate amount of IL 2 required to fully saturate their intrinsic proliferative capability. Surprisingly, the phenotypically least mature intrathymic T lymphocytes (T3 and T6 negative) respond to phytomitogen, at least in part, in an interleukin-dependent manner. It is noteworthy that a large proportion of these T3- and T6-negative thymocytes express IL 2 receptors and class II MHC antigens without in vitro activation. These novel findings have potential implications in the context of current models of differentiation pathways within the human thymus.     

Charybdotoxin-sensitive, Ca(2+)-dependent membrane potential changes are not involved in human T or B cell activation and proliferation.

The involvement of ion channels in B and T lymphocyte activation is supported by many reports of changes in ion fluxes and membrane potential after mitogen binding. Human T and B lymphocytes demonstrate an early and transient hyperpolarization after ligand binding. Inasmuch as the change in membrane potential is dependent on elevation of free cytosolic calcium, the hyperpolarization is presumably through opening of Ca(2+)-stimulated K+ channels. We have used charybdotoxin, a known inhibitor of Ca(2+)-dependent K+ channels, to study the role of these channels in lymphocyte activation and mitogenesis. We demonstrate that charybdotoxin inhibits the ligand-induced transient membrane hyperpolarization in B and T cells in a dose-dependent fashion, without affecting changes in cytosolic Ca2+. However, blockade of the Ca(2+)-activated K+ channel is not associated with changes in cell-cycle gene activation, IL-2 production, IL-2R expression or B and T cell mitogenesis. These results imply that membrane potential changes secondary to the ligand-dependent opening of Ca(2+)-activated K+ channels are not involved in B and T lymphocyte activation and mitogenesis.