Selective down modulation of L3T4 molecules on murine thymocytes by the tumor promoter, phorbol 12-myristate 13-acetate

Treatment of murine thymocytes, but not mature peripheral T cells, with the tumor promoter, phorbol 12-myristate 13-acetate (PMA), 3 results in a rapid disappearance of L3T4 molecules from the surface of thymocytes. The effect of PMA on L3T4 molecules persists in vitro for at least 72 hr. Down modulation of L3T4 molecules was PMA dose-dependent and temperature-dependent. L3T4 molecules on cortisone-resistant thymocytes were significantly less sensitive to the effect of PMA than were L3T4 molecules on cortisone-sensitive thymocytes. Down modulation of L3T4 molecules on thymocytes did not interfere with their capacity to respond to concanavalin A or activation signals delivered via their T cell receptors. The difference in the ability of thymocytes and peripheral T cells to respond to PMA cannot be explained by differences in the number of PMA receptors. Both thymocytes and peripheral T cells have PMA receptors in the range of 1 to 1.5 X 10(5) receptors/cell. However, there is a small difference in the affinity (Kd) of the receptors on thymocytes (Kd = 30 to 40 nM) and peripheral T cells (Kd = 10 to 15 nM). Immunofluorescent staining revealed that the down modulation of L3T4 molecules by PMA was a result of internalization of L3T4 molecules. After down modulation, L3T4 could be readily detected on the cytoplasm of thymocytes. These findings suggest that L3T4 molecules on thymocytes may be subject to different regulatory signals than L3T4 molecules on peripheral T cells.     

Modulation of the epidermal growth factor receptor by brain-derived growth factor in Swiss mouse 3T3 cells

Incubation of Swiss mouse 3T3 cells at 37 degrees C with bovine brain-derived growth factor (BDGF) decrease the cell surface 125I-EGF binding activity of these cells by 70-80%. This down-modulation of the EGF receptor by BDGF was time, temperature, and dose dependent. Scatchard plot analysis indicated that BDGF binding led to a selective decrease in the number of high-affinity EGF receptors. The BDGF-induced down-modulation of the EGF receptor was completely blocked by protamine, a potent inhibitor of receptor binding and mitogenic activities of BDGF. BDGF down-modulated the EGF receptor in phorbol myristic acetate (PMA)-pretreated cells, as well as in control cells. Furthermore, PMA-pretreated cells responded mitogenically to BDGF, whereas PMA itself failed to stimulate the mitogenic response of PMA-pretreated cells. This BDGF-induced down-modulation of the EGF receptor in PMA-desensitized cells suggests that BDGF down-regulates the EGF receptor by a mechanism distinct from that of PMA. Incubation of cells with compounds which are known to inhibit pinocytosis blocked the down-modulation induced either by BDGF or by platelet-derived growth factor (PDGF) but had no effect on the PMA-induced down-modulation. Incubation of cells with inhibitors of receptor recycling enhanced the BDGF-induced down-modulation of the EGF receptor. These results suggest that BDGF and PDGF induce down-modulation of the EGF receptor by increasing the internalization of cell surface high-affinity receptors and that the internalization process may not be required for down-modulation induced by PMA.     

Glycogen Synthase Kinase-3 modulates α1A-adrenergic receptor action and regulation

The possibility that glycogen synthase kinase 3 (GSK3) could modulate α_1A-adrenergic receptor (α_1A-AR) function and regulation was tested employing LNCaP and HEK293 cells transfected to express the enhanced green fluorescent protein-tagged human α_1A-AR. Receptor phosphorylation and internalization, intracellular free calcium, α_1A-AR-GSK3 colocalization, and coimmunoprecipitation were studied. The effects of the pharmacological GSK3 inhibitor, SB-216763, and the coexpression of a dominant-negative mutant of this kinase, as well as the signaling, desensitization, and internalization of receptors with S229, S258, S352, and S381 substitutions for alanine or aspartate, were also determined. SB-216763 inhibited agonist- and phorbol myristate acetate (PMA)-mediated α_1A-AR phosphorylation, reduced oxymetazoline-induced desensitization, and magnified that induced by PMA. Agonists and PMA increased receptor-GSK3 colocalization and coimmunoprecipitation. Expression of a dominant-negative GSK3 mutant reduced agonist- but not PMA-induced receptor internalization. α_1A-AR with the GSK3 putative target sites mutated to alanine exhibited reduced phosphorylation and internalization in response to agonists and increased PMA-induced desensitization. Agonist-induced, but not PMA-induced, receptor-β arrestin intracellular colocalization was diminished in cells expressing the GSK3 putative target sites mutated to alanine. Our data indicated that GSK3 exerts a dual action on α_1A-AR participating in agonist-mediated desensitization and internalization and avoiding PMA-induced desensitization.     

Nonequivalent effects of PKC activation by PMA on murine CD4 and CD8 cell-surface expression

The membrane glycoproteins CD4 (L3T4) and CD8 (Lyt2) are expressed on distinct populations of mature murine T lymphocytes, and are thought to be receptors for monomorphic determinants expressed on MHC class II and class I molecules, respectively. Although they differ in their ligand specificity, it has been presumed that CD4 and CD8 perform equivalent functions in the T cells that bear them. Since activation of protein kinase C (PKC) is known to cause rapid down-regulation of various receptors, including the T cell receptor complex (TcR complex), we treated cells with phorbol 12-myristate 13-acetate (PMA), a PKC activator, to determine whether cell-surface expression of CD4 and CD8 would be similarly affected by this intracellular mediator. Brief or relatively prolonged treatment with PMA induced mature murine T cells to reduce their surface expression of the TcR complex and of CD4, but not of CD8. Similarly, PMA rapidly induced transfected L cells to down-regulate surface CD4 expression, but had no effect on surface CD8 expression. Most significantly, PMA treatment induced CD4+CD8+ immature thymocytes to rapidly reduce their surface CD4 expression, but, again, it had no immediate effect on the surface expression of CD8. These results indicate that CD4 and TcR complex cell-surface expression are both sensitive to PKC activation by brief treatment with PMA, whereas CD8 expression is not, and suggest that CD4 and CD8 surface expression levels are regulated by distinct intracellular mechanisms.     

Phorbol ester-induced down modulation of tailless CD4 receptors requires prior binding of gp120 and suggests a role for accessory molecules.

The entry of human immunodeficiency virus type 1 into cells proceeds via a fusion mechanism that is initiated by binding of the viral glycoprotein gp120-gp41 to its cellular receptor CD4. Species- and tissue-specific restrictions to viral entry suggested the participation of additional membrane components in the postbinding fusion events. In a previous study (H. Golding, J. Manischewitz, L. Vujcic, R. Blumenthal, and D. Dimitrov, J. Virol. 68:1962-1968, 1994), it was found that phorbol myristate acetate (PMA) inhibits human immunodeficiency virus type 1 envelope-mediated cell fusion by inducing down modulation of an accessory component(s) in the CD4-expressing cells. The fusion inhibition was seen in a variety of cells, including T-cell transfectants expressing engineered CD4 receptors (CD4.401 and CD4.CD8) which are not susceptible to down modulation by PMA treatment. In the current study, it was found that preincubation of A2.01.CD4.401 cells with soluble monomeric gp120 for 1 h at 37 degrees C primed them for PMA-induced down modulation (up to 70%) of the tailless CD4 receptors. The gp120-priming effect was temperature dependent, and the down modulation may have occurred via clathrin-coated pits. Importantly, nonhuman cell lines expressing tailless CD4 molecules did not down modulate their CD4 receptors under the same conditions. The gp120-dependent PMA-induced down modulation of tailless CD4 receptors could be efficiently blocked by the human monoclonal antibodies 48D and 17B, which bind with increased avidity to gp120 that was previously bound to CD4 (M. Thali, J. P. Moore, C. Furman, M. Charles, D. D. Ho, J. Robinson, and J. Sodroski, J. Virol. 67:3978-3988, 1993). These findings suggest that gp120 binding to cellular CD4 receptors induces conformational changes leading to association of the gp120-CD4 complexes with accessory transmembrane molecules that are susceptible to PMA-induced down modulation and can target the virions to clathrin-coated pits.     

CD4 and CD8 are positive regulators of T cell receptor signal transduction in early T cell differentiation.

Although cortical (CD4+CD8+) thymocytes mobilize intracellular calcium poorly when CD3/TCR is ligated, we have found that murine cortical thymocytes can transduce strong biochemical signals in response to ligation of the CD3/Ti TCR complex (CD3/TCR) and that the signals are regulated by CD4 and CD8 interactions with CD3/TCR. Striking increases in intracellular calcium were observed in cortical thymocytes from transgenic mice containing productively rearranged alpha and beta TCR genes, when CD3 or TCR was cross-linked with CD4 or CD8 using heteroconjugated mAb. However, in mature T cells derived from lymph nodes of these mice, identical stimuli elicited calcium responses that were significantly smaller in magnitude. A thymocyte cell line that expresses a low level of the transgenic TCR and has a phenotype characteristic of cortical thymocytes (CD4+CD8+J11d+Thy-1+) was established from a female alpha beta TCR transgenic mouse. Cross-linking of CD4 or CD8 molecules to CD3/TCR induced strong calcium responses in these cells. Responses were weak or absent when CD3 or TCR were aggregated alone. Heteroconjugates of Thy-1xCD3 did not increase the intracellular calcium concentration in transgenic thymocytes or in the thymocyte cell line, although Thy-1 is highly expressed on immature cells. Enhanced tyrosine phosphorylation was observed when CD3 or TCR was cross-linked with CD4 or CD8 on transgenic thymocytes or on the thymocyte cell line, in comparison with aggregation of CD3/TCR alone. Taken together, these data show that CD4 and CD8 molecules allow the weakly expressed CD3/TCR of cortical thymocytes to transduce strong intracellular signals upon receptor ligation. These signals may be involved in selection processes at the CD4+CD8+ stage of differentiation.     

A monoclonal antibody reactive with a 40-kDa molecule on fetal thymocytes and tumor cells blocks proliferation and stimulates aggregation and apoptosis.

E710.2.3 is a murine thymic lymphoma cell line with an immature phenotype (CD4-CD8-) that proliferates in response to thymocytes or PMA when cultured at low density and proliferates spontaneously when grown at high density. To identify functional molecules on this cell line, we screened for mAbs that could block its proliferation. A hamster mAb, DMF10.62.3, inhibited the spontaneous, thymocyte-induced, and PMA-stimulated proliferation of E710.2.3 in vitro and induced these cells to undergo apoptosis. The mAb also caused homotypic aggregation of E710.2.3, which was inhibited by cytochalasin B, trifluoperazine, a combination of sodium azide and 2-deoxyglucose, EDTA, incubation at 4 degrees C, or treatment with paraformaldehyde. The DMF10 62.3 mAb stained a number of immortalized murine and human cell lines and, where tested, blocked their proliferation and caused death to varying extents by apoptosis. The molecule recognized by the mAb DMF10.62.3 was expressed on day 14 fetal thymus Thy1.2-positive cells. However, it was not detected on adult murine thymocytes, splenocytes, or bone marrow cells or on splenic LPS-activated B cells or Con A-activated T cells. The Ab immunoprecipitated a 40-kDa molecule from E710.2.3 that was not glycosylphosphatidylinositol linked. The data suggest that the molecule recognized by DMF62.3 is a novel cell surface molecule that may be involved in cell proliferation and/or cell death.     

Phosphorylation of paxillin via the ERK mitogen-activated protein kinase cascade in EL4 thymoma cells

Intracellular signals can regulate cell adhesion via several mechanisms in a process referred to as "inside-out" signaling. In phorbol ester-sensitive EL4 thymoma cells, phorbol-12-myristate 13-acetate (PMA) induces activation of extracellular signal-regulated kinase (ERK) mitogen-activated protein kinases and promotes cell adhesion. In this study, clonal EL4 cell lines with varying abilities to activate ERKs in response to PMA were used to examine signaling events occurring downstream of ERK activation. Paxillin, a multifunctional docking protein involved in cell adhesion, was phosphorylated on serine/threonine residues in response to PMA treatment. This response was correlated with the extent and time course of ERK activation. PMA-induced phosphorylation of paxillin was inhibited by compounds that block the ERK activation pathway in EL4 cells, primary murine thymocytes, and primary murine splenocytes. Paxillin was phosphorylated in vitro by purified active ERK2. Two-dimensional electrophoresis revealed that PMA treatment generated a complex pattern of phosphorylated paxillin species in intact cells, some of which were generated by ERK-mediated phosphorylation in vitro. An ERK pathway inhibitor interfered with PMA-induced adhesion of sensitive EL4 cells to substrate. These findings describe a novel inside-out signaling pathway by which the ERK cascade may regulate events involved in adhesion.     

A lymphocyte-specific protein tyrosine kinase, p56lck, regulates the PMA-induced internalization of CD4.

p56lck, a member of the src family of non-receptor protein tyrosine kinases (PTKs), is expressed predominantly in T-lymphocytes. Association of p56lck with CD4 and CD8 T-cell receptor (TcR) accessory molecules suggests that p56lck may play a specialized role in antigen-induced T-cell activation. CD4 and CD8 molecules are known to stabilize the interaction between TcR and the major histocompatibility complex during T-cell activation. To examine the role of p56lck in the dynamics of the CD4 molecule, p56lck-expressing transfectant cell clones were prepared by the transfection of an lck-gene plasmid containing an inducible promoter into a CD4+lck- human monocytoid cell line. When these transfectant cells were stimulated with phorbol ester, CD4 internalization on these p56lck-expressing cell lines was selectively and markedly retarded, as compared to p56lck-negative control cell lines. When cell-surface CD4 and intracellular CD4 were selectively precipitated after stimulation, the intracellular CD4 molecules were dissociated from p56lck whereas the surface-retained CD4 molecules were still associated with p56lck. Moreover, the dissociation of p56lck from CD4 appeared to occur prior to the PMA-induced internalization of CD4. These data indicate that p56lck regulates the PMA-induced internalization of CD4 possibly via its association with CD4. Treatment with genistein, a PTK inhibitor, revealed that the PTK activity of p56lck might not be involved in this regulatory effect of p56lck on CD4 internalization.     

Internalization, lysosomal degradation and new synthesis of surface membrane CD4 in phorbol ester-activated T-lymphocytes and U-937 cells.

Protein kinase C activating phorbol esters downregulated membrane CD4 by endocytosis in U-937 and human T-cells. Half-time for internalization (approximately 15 min at 50 ng/ml PMA) was determined by FACS. CD4-bound 125I-labeled anti-CD4 mAb was rapidly degraded in PMA-activated cells, whereas degradation was low in resting cells. Endocytosis and/or degradation of anti-CD4 mAb was suppressed by H7, and by inhibitors of membrane traffic (Monensin) and lysosome function (methylamine, chloroquine). Immunocytochemistry localized CD4 to the surface of unstimulated T-cells. Upon PMA stimulation occasional labeling was seen in endosomes but whole cell CD4 decreased dramatically. However, methylamine-treated PMA blasts showed accumulation of CD4 in lysosomes and accordingly, pulse-chase experiments in biolabeled cell cultures suggested a manifest reduction of CD4 half-life in response to PMA. Despite their low surface CD4 density, PMA blasts exhibited uptake and accelerated degradation of anti-CD4 mAb. Also, inhibitors of protein synthesis enhanced the PMA-induced downregulation, and membrane CD4 reappeared on fully activated as well as unstimulated cells treated with trypsin. Ongoing CD4 synthesis in activated cells was further evidenced by metabolic labeling and Northern blot analysis demonstrating unaltered or slightly increased CD4 protein and mRNA levels resulting from PMA. Our findings demonstrate that phorbol esters downregulate the cellular CD4 pool by endocytosis and subsequent lysosomal degradation of membrane CD4. Transport of CD4 to the cell surface and CD4 synthesis is unaffected by activation.     

Disparity between expression of transferrin receptor ligand binding and non-ligand binding domains on human lymphocytes

We compared transferrin receptor (TfR) expression on human peripheral blood lymphocytes (PBL) activated by phorbol myristate acetate (PMA) or L-phytohemagglutinin (LPHA) using two techniques: (1) 125I-iron-saturated transferrin (FeTf) binding, (2) reactivity with monoclonal anti-TfR antibodies--OKT9 and B3/25. These monoclonal antibodies do not block FeTf binding, and therefore bind to TfR domains separate from the ligand binding site. Unstimulated PBL bound fewer than 1,000 molecules of 125I-FeTf per cell, and less than 5% of cells expressed TfR antigens detected by OKT9 or B3/25. 125I-FeTf binding and antibody binding increased in parallel on LPHA-activated PBL. After exposure to LPHA for 72 hr, 125I-FeTf binding increased 100-fold to 10(5) molecules per cell and greater than 50% of cells expressed TfR antigens. By contrast, PMA activation of PBL markedly increased binding of OKT9 and B3/25 but not the binding of 125I-FeTf. Cell surface expression of TfR antigens seen by OKT9 and B3/25 did not differ between LPHA- and PMA-activated PBL. However, after 72 hr with PMA, 125I-FeTf binding increased only 6-fold and consistently remained at less than 10(4) molecules per cell. Therefore, PMA induced a disparity between expression of TfR ligand binding domains and immunological domains at the cell surface. Cell proliferation assessed by fluorescent DNA analysis was similar in cultures stimulated by LPHA or PMA. These data indicate that lymphoid cells may possess a mechanism for modulating TfR expression in which down-regulation of FeTf binding occurs without receptor internalization. Alternatively, it is possible that this observation may reflect a membrane perturbation effect of PMA.     

Lymphocyte chemoattractant factor induces CD4-dependent intracytoplasmic signaling in lymphocytes.

At present, a naturally occurring soluble ligand for CD4 has not been well described. There is much evidence to indicate that MHC class II molecules can bind to CD4; however, binding of intact class II molecules under physiologic conditions has been difficult to demonstrate. We investigated whether a previously reported human lymphokine, lymphocyte chemoattractant factor (LCF), which was described for its effects on human CD4+ lymphocytes and monocytes, could associate directly with CD4 and induce the generation of second messengers. In the present study, we demonstrate that CD4 affinity-purified natural and recombinant LCF induced a rise in intracellular calcium and increased inositol trisphosphate generation in normal human CD4+ lymphocytes and murine T cell hybridomas infected to express human CD4. Cell lines lacking human CD4 or expressing human CD4 molecules that lack the intracytoplasmic domain did not demonstrate a change in either calcium or inositol trisphosphate. The effect of LCF was blocked by coincubation with either anti-CD4 antibody or Fab fragments from anti-CD4 antibody. These studies demonstrate direct interaction of a lymphokine with CD4 and generation of second messengers as a result of the interaction.     

CD4 and CD7 molecules as targets for drug delivery from antibody bearing liposomes.

We have examined two T lymphocyte cell surface molecules, CD4 and CD7, as targets for specific delivery of drugs from antibody-directed liposomes. The efficiency of uptake by peripheral lymphocytes, thymocytes, and two CEM sublines (CEM.MRS and CEM-T4) of anti-CD4 and anti-CD7 liposomes containing methotrexate was evaluated by the methotrexate-mediated inhibition of the incorporation of d-[3H]Urd into DNA. This was compared with similar liposomes targeted to MHC-encoded HLA class I molecules, which are known to be efficiently taken up by T cells. Despite the lower expression of CD7 molecules relative to HLA class I on most cell lines, CD7 was shown to be a good target for drug delivery. The results of an internalization study using radiolabeled Protein A showed that a higher proportion of CD7 molecules was internalized than HLA class I molecules. CD4-targeted liposomes, in contrast, were relatively ineffective for drug delivery for lymphoid cells, and only partially inhibited CEM-T4 cells. The lack of toxicity correlated with poor internalization of the target molecule on most cell lines. The drug effect of anti-CD4 liposomes was more pronounced on HeLa-T4, which is an epithelial cell line transfected with the CD4 gene. In contrast to lymphoid cells, these cells efficiently internalized CD4 molecules. PMA is known to down-regulate surface expression of CD4 molecules on various T cells. Internalization of CD4 was induced by PMA, but PMA failed to induce cytotoxicity of CD4-targeted liposomes for CEM.MRS. The internalized drug was probably degraded rapidly because internalized anti-CD4 antibody-bound Protein A was degraded very rapidly.     

Cell surface comodulation of CD4 and T cell receptor by anti-CD4 monoclonal antibody

In our study we have used anti-CD4 mAb to investigate the cell surface association between CD4 and the Ag-specific TCR complex on mature peripheral T cells. Anti-CD4 mAb was administered in vivo and in vitro and its effects on CD4 and CD3 cell surface expression were determined. In vivo, anti-CD4 mAb reduced cell surface expression of its ligand, CD4, and secondarily also reduced cell surface expression of CD3/TCR on CD4+ splenic T cells. In vitro, multivalent cross-linking of CD4 by anti-CD4 mAb and either FcR+ cells or anti-Ig mAb also resulted in decreased surface expression of CD4 and specific comodulation of CD3/TCR. The secondary reduction in cell surface CD3/TCR expression induced by CD4 cross-linking could be pharmacologically disrupted by high doses of PMA, indicating that the comodulation of CD3 with CD4 was dependent upon intracellular mediators, possibly including protein kinase C. These results demonstrate that, in the presence of anti-CD4 mAb, CD4 is functionally associated with the CD3/TCR complex, and that this association is dependent upon the activity of intracellular mediators. Such intracellular mediators might induce the coordinate down-modulation of physically unassociated CD4 and CD3/TCR molecules, or, alternatively, might promote a physical interaction between CD4 and CD3/TCR molecules.     

Heterologous activation of protein kinase C stimulates phosphorylation of delta-opioid receptor at serine 344, resulting in beta-arrestin- and clathrin-mediated receptor internalization

The purpose of the current study is to investigate the effect of opioid-independent, heterologous activation of protein kinase C (PKC) on the responsiveness of opioid receptor and the underlying molecular mechanisms. Our result showed that removing the C terminus of delta opioid receptor (DOR) containing six Ser/Thr residues abolished both DPDPE- and phorbol 12-myristate 13-acetate (PMA)-induced DOR phosphorylation. The phosphorylation levels of DOR mutants T352A, T353A, and T358A/T361A/S363S were comparable to that of the wild-type DOR, whereas S344G substitution blocked PMA-induced receptor phosphorylation, indicating that PKC-mediated phosphorylation occurs at Ser-344. PKC-mediated Ser-344 phosphorylation was also induced by activation of G(q)-coupled alpha(1A)-adrenergic receptor or increase in intracellular Ca(2+) concentration. Activation of PKC by PMA, alpha(1A)-adrenergic receptor agonist, and ionomycin resulted in DOR internalization that required phosphorylation of Ser-344. Expression of dominant negative beta-arrestin and hypertonic sucrose treatment blocked PMA-induced DOR internalization, suggesting that PKC mediates DOR internalization via a beta-arrestin- and clathrin-dependent mechanism. Further study demonstrated that agonist-dependent G protein-coupled receptor kinase (GRK) phosphorylation sites in DOR are not targets of PKC. Agonist-dependent, GRK-mediated receptor phosphorylation and agonist-independent, PKC-mediated DOR phosphorylation were additive, but agonist-induced receptor phosphorylation could inhibit PKC-catalyzed heterologous DOR phosphorylation and subsequent internalization. These data demonstrate that the responsiveness of opioid receptor is regulated by both PKC and GRK through agonist-dependent and agonist-independent mechanisms and PKC-mediated receptor phosphorylation is an important molecular mechanism of heterologous regulation of opioid receptor functions.     

Comparison of the capacity of murine and human class I MHC molecules to stimulate T cell activation.

The mechanism underlying the apparent differences in the capacity of murine and human class I MHC molecules to function as signal transducing structures in T cells was examined. Cross-linking murine class I MHC molecules on splenic T cells did not stimulate an increase in intracellular calcium ([Ca2+]i) and failed to induce proliferation in the presence of IL-2 or PMA. In contrast, modest proliferation was induced by cross-linking class I MHC molecules on murine peripheral blood T cells or human class I MHC molecules on murine transgenic spleen cells, but only when costimulated with PMA. Moreover, cross-linking murine class I MHC molecules or the human HLA-B27 molecule on T cell lines generated from transgenic murine splenic T cells stimulated only modest proliferation in the presence of PMA, but not IL-2. On the other hand, cross-linking murine class I MHC molecules expressed by the human T cell leukemic line, Jurkat, transfected with genes for these molecules, generated a prompt increase in [Ca2+]i, and stimulated IL-2 production in the presence of PMA. The results demonstrate that both murine and human class I MHC molecules have the capacity to function as signal transducing structures, but that murine T cells are much less responsive to this signal.     

CD45 negatively regulates monocytic cell differentiation by inhibiting phorbol 12-myristate 13-acetate-dependent activation and tyrosine phosphorylation of protein kinase Cdelta

The protein-tyrosine phosphatase CD45 is expressed on all monocytic cells, but its function in these cells is not well defined. Here we report that CD45 negatively regulates monocyte differentiation by inhibiting phorbol 12-myristate 13-acetate (PMA)-dependent activation of protein kinase C (PKC) delta. We found that antisense reduction of CD45 in U937 monocytic cells (CD45as cells) increased by 100% the ability of PMA to enlarge cell size, increase cell cytoplasmic process width and length, and induce surface expression of CD11b. In addition, reduction in CD45 expression caused the duration of peak PMA-induced MEK and extracellular signal-regulated kinase (ERK) 1/2 activity to increase from 5 min to 30 min while leading to a 4-fold increase in PMA-dependent PKCdelta activation. Importantly, PMA-dependent tyrosine phosphorylation of PKCdelta was also increased 4-fold in CD45as cells. Finally, inhibitors of MEK (PD98059) and PKCdelta (rottlerin) completely blocked PMA-induced monocytic cell differentiation. Taken together, these data indicate that CD45 inhibits PMA-dependent PKCdelta activation by impeding PMA-dependent PKCdelta tyrosine phosphorylation. Furthermore, this blunting of PKCdelta activation leads to an inhibition of PKCdelta-dependent activation of ERK1/2 and ERK1/2-dependent monocyte differentiation. These findings suggest that CD45 is a critical regulator of monocytic cell development.     

Mechanism of action of phorbol myristate acetate on human natural killer cell activity

We have investigated the kinetics of inhibition and regeneration of human natural killer (NK) cell-mediated lysis of K562, a human erythroleukemia cell line, by the potent tumor-promoting agent phorbol-12-myristate-13-acetate (PMA). It is shown that PMA inhibits NK cell-mediated cytotoxicity (CMC) in a dose-dependent manner whether the compound is present throughout the 4-hr cytotoxic assay or the effector cells (EC) are pretreated with PMA. Pretreatment of the target cells (TC) with PMA produced a different profile of NK activity suggesting that PMA inhibition of NK-CMC is primarily due to the inactivation of EC. PMA-induced inhibition of NK-CMC does not affect TC binding and is not circumvented by compounds that enhance intracellular levels of cyclic guanosine monophosphate (cGMP) or calcium. Furthermore, and contrary to a recent report, PMA-induced inhibition of NK-CMC is independent of monocytes. Finally, kinetic studies revealed that PMA-induced inhibition of NK-CMC occurs rapidly and is fully reversible provided that “regenerated EC” are thoroughly washed, prior to the cytotoxic assay, to rid the cell suspension of residual PMA. The potential implications of these results to the currently accepted theory of TC destruction by NK cells, the stimulus-secretion model, are discussed.     

A Role for the MEK/MAPK Pathway in PMA-Induced Cell Cycle Arrest: Modulation of Megakaryocytic Differentiation of K562 Cells

In vitromegakaryocytic differentiation of the pluripotent K562 human leukemia cell line is induced by PMA. Treatment of K562 cells with PMA results in growth arrest, polyploidy, morphological changes, and increased cell–cell and cell–substrate adhesion. These PMA-induced changes in K562 cells are preceded by a rapid rise in the activity of MEK (MAP kinase/extracellular regulated kinases) that leads to a sustained activation of ERK2 (extracellular regulated kinase; MAPK). Blockade of MEK1 activation by PD098059, a recently described specific MEK inhibitor [D. T. Dudleyet al.(1995).Proc. Natl. Acad. Sci. USA92, 7686–7689], reverses both the growth arrest and the morphological changes of K562 cells induced by PMA treatment. These changes are not associated with a disruption of PMA-induced down-regulation of BCR-ABL kinase or early integrin signaling events but are associated with a block of the cell-surface expression of the gpIIb/IIIa (CD41) integrin, a cell marker of megakaryocytic differentiation. These results demonstrate that the PMA-induced signaling cascade initiated by protein kinase C activation requires the activity of the MEK/ERK signaling complex to regulate cell cycle arrest, thus regulating the program that leads to the cell-surface expression of markers associated with megakaryocytic differentiation.