Reciprocal regulation of protein kinase C isoforms results in differential cellular responsiveness

Immunological homeostasis is often maintained by counteractive functions of two different cell types or two different receptors signaling through different intermediates in the same cell. One of these signaling intermediates is protein kinase C (PKC). Ten differentially regulated PKC isoforms are integral to receptor-triggered responses in different cells. So far, eight PKC isoforms are reported to be expressed in macrophages. Whether a single receptor differentially uses PKC isoforms to regulate counteractive effector functions has never been addressed. As CD40 is the only receptor characterized to trigger counteractive functions, we examined the relative role of PKC isoforms in the CD40-induced macrophage functions. We report that in BALB/c mouse macrophages, higher doses of CD40 stimulation induce optimum phosphorylation and translocation of PKCα, βI, βII, and ε whereas lower doses of CD40 stimulation activates PKCδ, ζ, and λ. Infection of macrophages with the protozoan parasite Leishmania major impairs PKCα, βI, βII, and ε isoforms but enhances PKCδ, ζ, and λ isoforms, suggesting a reciprocity among these PKC isoforms. Indeed, PKCα, βI, βII, and ε isoforms mediate CD40-induced p38MAPK phosphorylation, IL-12 expression, and Leishmania killing; PKCδ and ζ/λ mediate ERK1/2 phosphorylation, IL-10 production, and parasite growth. Treatment of the susceptible BALB/c mice with the lentivirally expressed PKCδ- or ζ-specific short hairpin RNA significantly reduces the infection and reinstates host-protective IFN-γ-dominated T cell response, defining the differential roles for PKC isoforms in immune homeostasis and novel PKC-targeted immunotherapeutic and parasite-derived immune evasion strategies.     

Antagonism between interleukin 3 and erythropoietin in mice with azidothymidine-induced anemia and in bone marrow endothelial cells

Azidothymidine (AZT)-induced anemia in mice can be reversed by the administration of IGF-IL-3 (fusion protein of insulin-like growth factor II (IGF II) and interleukin 3). Although interleukin 3 (IL-3) and erythropoietin (EPO) are known to act synergistically on hematopoietic cell proliferation in vitro, injection of IGF-IL-3 and EPO in AZT-treated mice resulted in a reduction of red cells and an increase of plasma EPO levels as compared to animals treated with IGF-IL-3 or EPO alone. We tested the hypothesis that the antagonistic effect of IL-3 and EPO on erythroid cells may be mediated by endothelial cells. Bovine liver erythroid cells were cultured on monolayers of human bone marrow endothelial cells previously treated with EPO and IGF-IL-3. There was a significant reduction of thymidine incorporation into both erythroid and endothelial cells in cultures pre-treated with IGF-IL-3 and EPO. Endothelial cell culture supernatants separated by ultrafiltration and ultracentrifugation from cells treated with EPO and IL-3 significantly reduced thymidine incorporation into erythroid cells as compared to identical fractions obtained from the media of cells cultured with EPO alone. These results suggest that endothelial cells treated simultaneously with EPO and IL-3 have a negative effect on erythroid cell production.     

蛋白激酶C亚型在HL—60细胞诱导分化中的变化

用全反式维甲酸（ＡＴＲＡ）或佛波酯（ＰＭＡ）处理人早幼粒白血病细胞（ＨＬ－６０）３天,用形态学,ＮＢＴ还原实验,特异性和非特异性酯酶测定,证明细胞分别向粒细胞或单核／巨噬细胞分化。通过免疫组化法观察了蛋白激酶Ｃ（ＰＫＣ）α,βⅠ和βⅡ亚型在分化后的变化。结果显示,ＡＴＲＡ可引起ＨＬ－６０细胞ＰＫＣα,βⅠ和βⅡ的含量升高,分别为对照的５．０,２．８和４．２倍,并存在从胞膜向胞质转位。ＰＭＡ则使ＰＣ     

Establishment and characterization of a unique human cell line that proliferates dependently on GM-CSF, IL-3, or erythropoietin

We have established a novel cell line, designated as TF-1, from a patient with erythroleukemia, which showed complete growth dependency on granulocyte-macrophage colony-stimulating factor (GM-CSF) or on interleukin-3 (IL-3) and carried a homogeneous chromosomal abnormality (54X). Erythropoietin (EPO) also sustained the short-term growth of TF-1, but did not induce erythroid differentiation. These three hematopoietic growth factors acted on TF-1 synergistically. Transforming growth factor-beta and interferons inhibited the factor-dependent growth of TF-1 cells in a dose-dependent fashion, and monocyte-colony stimulating factor and interkeukin-1 enhanced the GM-CSF-dependent growth of TF-1. Ultrastructural studies revealed some very immature features in this cell line. Although TF-1 cells do not express glycophorin A or carbonyl anhydrase I, the morphological and cytochemical features, and the constitutive expression of globin genes, indicate the commitment of TF-1 to erythroid lineage. When induced to differentiate, TF-1 entered two different pathways. Specifically, hemin and delta-aminolevulinic acid induced hemoglobin synthesis, whereas TPA induced dramatic differentiation of TF-1 into macrophage-like cells. In summary, TF-1 is a cell line of immature erythroid origin that requires GM-CSF, IL-3, or EPO for its growth and that has the ability to undergo differentiation into either more mature erythroid cells or into macrophage-like cells. TF-1 is a useful tool for analyzing the human receptors for IL-3, GM-CSF, and EPO or the signal transduction of these hemopoietic growth factors.     

Expression of the functional erythropoietin receptors on interleukin 3-dependent murine cell lines

Two distinct hemopoietic growth factors, interleukin 3 (IL-3) and erythropoietin (EPO), support the growth and development of erythroid cells in a sequential manner in vitro. Stimulation of multipotential stem cells by IL-3 appears to develop committed erythroid progenitor cells that respond to EPO. When several murine IL-3-dependent cell lines were assayed for their ability to respond to EPO, the growth and survival of the three cell lines showing the profiles of either myeloid or mast cell lineage (IC-2, DA-1, FDC-P2) were stimulated by EPO in a dose-dependent fashion. To determine whether the biologic effects were mediated through the specific receptors for EPO, we performed binding experiments on these cells with radioiodinated EPO. All of these cells displayed significant levels of specific binding for EPO. Among a family of hemopoietic growth factors, only unlabeled EPO was able to compete for the binding of radioiodinated EPO to the cells. Analysis of the binding data revealed the existence of a single case of binding sites in extremely low abundance. IC-2 cells were used to study the effects of IL-3 on the regulation of expression of EPO receptors. It was demonstrated that a decrease in IL-3 concentration in the culture medium increased the responsiveness to EPO and the amount in specific binding of EPO as well. These results suggest that some IL-3-dependent cell lines have functional EPO receptors and their expression may be modulated by IL-3.     

Stromal cells provide signals different from cytokines for STAT5 activation in hematopoietic cells

After detachment from the stromal cells, hematopoietic stem cells are thought to differentiate to the cytokine-dependent stages where their growth and differentiation are promoted by these cytokines. To examine the stromal regulation of hematopoietic stem cells, we previously established a primitive hematopoietic stem-like cell line, THS119, whose growth was dependent on the bone marrow stromal cell line, TBR59, and from which IL-3- (THS119/IL-3) or IL-7- (THS119/IL-7) dependent cell lines were then generated. Using these cell lines, we examined the difference in signals mediated by the stromal cells and cytokines. The cytokine-dependent cell lines (THS119/IL-3 and THS119/IL-7) showed induction of STAT5 phosphorylation and target genes for STAT5 such as CIS, pim-1, p21 and bcl-xL upon addition of IL-3 or IL-7. IL-3 or IL-7 also induced STAT5 phosphorylation and STAT5 target genes of the stromal cell-dependent cell line, THS119, in the absence of stromal cells at levels similar to the cytokine-dependent cell lines. However, quite interestingly, TBR59 stromal cells could not induce STAT5 phosphorylation of THS119 cells, although they did induce STAT5 target genes in THS119 cells. In addition, the mRNAs for STAT5 target genes in THS119 cells on the stromal cells seemed to be more stable than those in the cytokine-dependent cell lines. Expression of the antiapoptotic genes bcl-2 and bcl-xL was higher in the stromal cell-dependent cell line than in the cytokine-dependent cell lines. These results suggested that stromal cells and cytokines may provide different signals for growth and differentiation of the hematopoietic cells.     

Selection of lineage-restricted cell lines immortalized at different stages of hematopoietic differentiation from the murine cell line 32D

Erythropoietin (Epo), granulocyte-macrophage colony-stimulating factor (GM-CSF) and granulocyte colony-stimulating factor- (G-CSF) dependent cell lines have been derived from the murine hematopoietic cell line 32D with a selection strategy involving the culture of the cells in FBS-deprived medium supplemented only with pure recombinant Epo, GM-CSF, or G-CSF. The cells retain the diploid karyotype of the original 32D clone, do not grow in the absence of exogenous growth factor, and do not induce tumors when injected into syngeneic recipients. The morphology of the Epo-dependent cell lines (32D Epo1, -2, and -3) was heterogeneous and evolved with passage. The percent of differentiated cells also was a function of the cell line investigated. Benzidine-positive cells ranged from 1-2% (32D Epo3) to 50-60% (32D Epo1). These erythroid cells expressed carbonic anhydrase I and/or globin mRNA but not carbonic anhydrase II. The GM-CSF- and G-CSF-dependent cell lines had predominantly the morphology of undifferentiated myeloblasts or metamyelocytes, respectively. The GM-CSF-dependent cell lines were sensitive to either GM-CSF or interleukin-3 (IL-3) but did not respond to G-CSF. The G-CSF-dependent cell lines grew to a limited extent in IL-3 but did not respond to GM-CSF. These results indicate that the cell line 32D, originally described as predominantly a basophil/mast cell line, has retained the capacity to give rise to cells which proliferate and differentiate in response to Epo, GM-CSF, and/or G-CSF. These cells represent the first nontransformed cell lines which can be maintained in growth factors other than IL-3 and which differentiate in the presence of physiologic signals. As such, they may represent a model to study the molecular mechanisms underlying the process of hematopoietic differentiation, as well as sensitive targets for bioassays of specific growth factors.     

Protein kinase C alpha protein expression is necessary for sustained erythropoietin production in human hepatocellular carcinoma (Hep3B) cells exposed to hypoxia.

Although protein kinase C (PKC) has been implicated as an effector of erythropoietin (EPO) production, its exact role is still uncertain. Hep3B human hepatocellular carcinoma cells were used for this study and were depleted of PKC in three different ways: long-term treatment with phorbol 12-myristate 13-acetate (PMA), selective inhibition with calphostin C, and treatment with PKCalpha antisense oligonucleotides. When EPO-producing Hep3B cells were incubated in 1% O2 (hypoxia) for 24 h, PMA treatment resulted in significant decreases in medium levels of EPO in Hep3B cell cultures at concentrations higher than 10 nM. The specific PKC inhibitor, calphostin C, significantly inhibited medium levels of EPO and EPO mRNA levels in Hep3B cells exposed to 1% O2. Western blot analysis revealed that Hep3B cells express the classical PKCalpha and gamma isoforms, as well as novel PKCepsilon and delta and the atypical zeta isoform. Preincubation with PMA for 6 h specifically down-regulated PKCalpha protein expression. Phosphorothioate modified antisense oligonucleotides specific for PKCalpha also decreased EPO production in Hep3B cells exposed to hypoxia for 20 h when compared to PKCalpha sense treatment. The translocation of PKCalpha from the soluble to particulate fractions was increased in Hep3B cells incubated under hypoxia compared with normoxia (21% O2) controls. These results suggest that the PKCalpha isoform plays an important role in sustaining hypoxia-regulated EPO production.     

The Roles of Protein Kinase C βI and βII in Vascular Smooth Muscle Cell Proliferation

The role of protein kinase C (PKC) on proliferation of A10 vascular smooth muscle cells (VSMC) was studied by overexpressing specific PKC-βI and -βII isozymes. PKC-βI and -βII are derived from alternative splicing of the exon encoding the carboxy-terminal (C-terminal) 50 or 52 amino acids, respectively. The differential functions of the two isozymes with regard to cell proliferation, DNA synthesis, and the cell cycle were investigated in A10 cells, a clonal cell line of VSMC from rat aorta, and in A10 cells overexpressing PKC-βI and PKC-βII (βI-A10 and βII-A10). PKC levels were increased three- to fourfold in heterogeneous cultures of stably transfected cells. Although doubling time of A10 cells was 36 h, the cell doubling time in βI-A10 cells decreased by 12 h, and, in contrast, the doubling time of βII-A10 cells increased by 12 h compared to A10 cells. The increase of [³H]thymidine (TdR) incorporation was accelerated and increased in βI-A10 cells, but slowed and diminished in βII-A10 cells compared to A10 and control cells transfected with empty vector. Cell cycle analysis of βI-A10 cells showed an acceleration of S phase entry while βII-A10 cells slowed S phase entry. These results suggest that PKC-βI and PKC-βII regulate cell proliferation bidirectionally and that PKC-βI and PKC-βII may have distinct and opposing functions as cell cycle check point mediators during late G₁phase and may regulate S phase entry in A10 VSMC.     

Cytokine-induced phosphorylation of pp100 in FDC-ER cells is at tyrosine residues.

Using FDC-P1 cells stably transfected with a murine erythropoietin receptor cDNA as a model, we recently have shown that erythropoietin (EPO), IL-3 and GM-CSF each induce the rapid phosphorylation of a common cytosolic target, i.e., a M(r) 100,000 phosphoprotein "pp100". Presently, we demonstrate that cytokine-induced phosphorylation of pp100 is primarily at tyrosine residues. This is shown by Western blotting with the anti-phosphotyrosine antibody PY20, and by the resistance of [32P]-pp100 to hydroxide-mediated hydrolysis of phosphates. These data, together with the recent observation by Linnekin et al. that pp100/p97 apparently associates directly with EPO receptors, suggest that pp100 may comprise an immediate common component in the signal transduction pathways of EPO, IL-3, GM-CSF and possibly other type I/II cytokine receptors. Additional analyses suggest that pp100 is distinct from a previously described M(r) 100,000 cytosolic target which is tyrosine phosphorylated in hematopoietic cells upon activation of T-cell receptors.     

Effects of Depolarization and NMDA Antagonists on the Survival of Cerebellar Granule Cells: A Pivotal Role for Protein Kinase C Isoforms

Abstract: Primary cultures of cerebellar granule cells (CGCs) grown in high-K⁺ (25 mM; K25) medium progressively differentiate in vitro. Differentiation is noticeable after 3–4 days in vitro (DIV) and reach a mature stage after 8 DIV. Longer cultivation of CGCs (>13 DIV) triggers the processes of spontaneous cell death. However, if cultured in normal physiological K⁺ concentration (5 mM; K5), a significant proportion of the cells dies by the end of the first week in culture. To address the role of protein kinase C (PKC) in the development of CGCs, we measured the kinase activity as well as the protein level of the kinase isoforms. As the K25 CGC culture proceeded, the PKC activity time-dependently increased by 3.2-fold, reaching a steady state at 8 DIV. Western blot analysis using PKC isoform-specific antibodies revealed an increase in levels of PKC α, γ, μ, λ, and ι from 2 to 8 DIV. A slight increase or decrease at 4 DIV was observed for PKC ε and βII, respectively, whereas no significant change was observed for βI. The isoforms of δ, θ, η, and ζ were not detected. Comparing the 14 DIV cultures with the 10 DIV cultures, the immunoreactivities of PKC ι and ε were decreased, those of PKC α, βI, βII, γ, and λ were unchanged, whereas that of PKC μ was still increased. In K5 cultures, the immunoreactivity of each PKC isoform at 2–4 DIV was similar to that observed in K25 cells, although no remarkable differentiation features were observed. Coordinated with the appearance of cell death at 8 DIV in low-K⁺ cultures, levels of PKC α, μ, λ, and ι, but not the others, were markedly decreased. The NMDA receptor antagonists MK-801 and 2-amino-5-phosphopentanoic acid markedly prevented the age-induced apoptosis of CGCs, and the cells survived >18 DIV under these conditions. The cytoprotective effect of MK-801 was concomitant with the increases in levels of PKC γ, λ, ι, and μ at 10 and 14 DIV. In addition, the PKC ε level was increased at 14 DIV but decreased at early stages, whereas PKC α, βI, and βII levels were unchanged, as compared with K25 culture alone. Taken together, induction and up-regulation of PKC isoforms may play an important role in the maintenance of CGC survival by depolarization and MK-801.     

Three dimensional cultures of rat liver cells using a natural self-assembling nanoscaffold in a clinically relevant bioreactor for bioartificial liver construction

Till date, no bioartificial liver (BAL) procedure has obtained FDA approval or widespread clinical acceptance, mainly because of multifactorial limitations such as the use of microscale or undefined biomaterials, indirect and lower oxygenation levels in liver cells, short-term undesirable functions, and a lack of 3D interaction of growth factor/cytokine signaling in liver cells. To overcome preclinical limitations, primary rat liver cells were cultured on a naturally self-assembling peptide nanoscaffold (SAPN) in a clinically relevant bioreactor for up to 35 days, under 3D interaction with suitable growth factors and cytokine signaling agents, alone or combination (e.g., Group I: EPO, Group II: Activin A, Group III: IL-6, Group IV: BMP-4, Group V: BMP4 + EPO, Group VI: EPO + IL-6, Group VII: BMP4 + IL-6, Group VIII: Activin A + EPO, Group IX: IL-6 + Activin A, Group X: Activin A + BMP4, Group XI: EPO + Activin A + BMP-4 + IL-6 + HGF, and Group XII: Control). Major liver specific functions such as albumin secretion, urea metabolism, ammonia detoxification, phase contrast microscopy, immunofluorescence of liver specific markers (Albumin and CYP3A1), mitochondrial status, glutamic oxaloacetic transaminase (GOT) activity, glutamic pyruvic transaminase (GPT) activity, and cell membrane stability by the lactate dehydrogenase (LDH) test were also examined and compared with the control over time. In addition, we examined the drug biotransformation potential of a diazepam drug in a two-compartment model (cell matrix phase and supernatant), which is clinically important. This present study demonstrates an optimized 3D signaling/scaffolding in a preclinical BAL model, as well as preclinical drug screening for better drug development.     

Functional alterations in protein kinase C beta II expression in melanoma

Protein kinase C (PKC) is a heterogeneous family of serine/threonine protein kinases that have different biological effects in normal and neoplastic melanocytes (MCs). To explore the mechanism behind their differential response to PKC activation, we analyzed the expression profile of all nine PKC isoforms in normal human MCs, HPV16 E6/E7 immortalized MCs, and a panel of melanoma cell lines. We found reduced PKCβ and increased PKCζ and PKCι expression at both the protein and mRNA levels in immortalized MCs and melanoma lines. We focused on PKCβ as it has been functionally linked to melanin production and oxidative stress response. Re-expression of PKCβ in melanoma cells inhibited colony formation in soft agar, indicating that PKCβ loss in melanoma is important for melanoma growth. PKCβII, but not PKCβI, was localized to the mitochondria, and inhibition of PKCβ significantly reduced UV-induced reactive oxygen species (ROS) in MCs with high PKCβ expression. Thus alterations in PKCβ expression in melanoma contribute to their neoplastic phenotype, possibly by reducing oxidative stress, and may constitute a selective therapeutic target.     

Activation of protein kinase C isozymes is associated with post-mitotic events in intestinal epithelial cells in situ

The mechanisms underlying control of cell growth and differentiation in epithelial tissues are poorly understood. Protein kinase C (PKC) isozymes, members of a large family of serine/threonine kinases of fundamental importance in signal transduction, have been increasingly implicated in the regulation of cell growth, differentiation, and function. Using the rat intestinal epithelium as a model system, we have examined PKC-specific activity as well as individual PKC isozyme expression and distribution (i.e., activation status) in epithelial cells in situ. Increased PKC activity was detected in differentiating and functional cells relative to immature proliferating crypt cells. Immunofluorescence and Western blot analysis using a panel of isozyme- specific antibodies revealed that PKC alpha, beta II, delta, epsilon, and zeta are expressed in rat intestinal epithelial cells and exhibit distinct subcellular distribution patterns along the crypt-villus unit. The combined morphological and biochemical approach used permitted analysis of the activation status of specific PKC isozymes at the individual cell level. These studies showed that marked changes in membrane association and level of expression for PKC alpha, beta II, delta, and zeta occur as cells cease division in the mid-crypt region and begin differentiation. Additional changes in PKC activation status are observed with acquisition of mature function on the villus. These studies clearly demonstrate naturally occurring alterations in PKC isozyme activation status at the individual cell level within the context of a developing tissue. Direct activation of PKC in an immature intestinal crypt cell line was shown to result in growth inhibition and coincident translocation of PKC alpha from the cytosolic to the particulate subcellular fraction, paralleling observations made in situ and providing further support for a role of intestinal PKC isozymes in post-mitotic events. PKC isozymes were also found to be tightly associated with cytoskeletal elements, suggesting participation in control of the structural organization of the enterocyte. Taken together, the results presented strongly suggest an involvement of PKC isoforms in cellular processes related to growth cessation, differentiation, and function of intestinal epithelial cells in situ.     

STAT1 is involved in signal transduction in the EPO induced HEL cells

Erythropoietin(EPO) is the major regulator of mamalian erythropoisis,which stimulates the growth and differentiation of hematopoietic cells through interaction with its receptor(EPO-R),Here we use HEL cells (a human erythro-leukemia cell line) as a model to elucidate the pathway of signal transduction in the EPO-induced HEL cells.Our data show that the EPOR (EPO receptor) on the surface of HEL cells interacts with the Janus tyrosine protein kinase(Jak2) to transduce intracellular signals through phosphorylation of cytoplasmic proteins in EPO-treated HEL cells.Both STAT1 and STAT5 in this cell line are tyrosine-phosphorylated and translocated to nucleus following the dinding of EPO to HEL cells.Furthermore,the dinding of both STAT1 and STAT5 proteins to specific DNA elements(SIE and PIE elements) is revealed in an EPO-dependent manner,Our data demonstrate that the pathway of signal transduction following the binding of EPO to HEL cells is similar to immature eryhroid cell from the spleen of mice infected with anemia strain of Friend virus.     

Human T cell activation by phorbol esters and diacylglycerol analogues

Activation of protein kinase C (PKC), by the phorbol ester PMA, or the membrane-permeable diacylglycerol 1-oleoyl 2-acetylglycerol (OAG), had different effects on the proliferation-associated responses of a more than 99% pure population of human T cells. Treatment with PMA or OAG caused down-regulation of the TCR-CD3 complex, but only PMA, in combination with ionomycin, was capable of stimulating IL-2R expression and proliferation. Immunocytochemical staining with antisera specific for the PKC subspecies alpha, beta I, beta II, and gamma showed that untreated resting T cells normally coexpress alpha, beta I, and beta II PKC subspecies, which are distributed diffusely throughout the cell, with some localization around the periphery of the nucleus. There was no difference between the responses of these PKC subspecies to OAG and PMA, redistributing, after 10 min of treatment, to a discrete focal area within the cell. Treatment with OAG resulted in transient redistribution of PKC, maximal at 10 min, while in PMA-stimulated cells, the PKC redistribution was prolonged, persisting for at least 24 h. The results suggest that the difference in cellular response to treatment with PMA and OAG is not a consequence of differential activation of various PKC subspecies.     

Regulation of actin cytoskeleton in lymphocytes: PKC-delta disrupts IL-3-induced membrane ruffles downstream of Rac1

In the murine pre-B lymphoid cell line Baf3, the presence of IL-3 is required for the formation of membrane ruffles that intensely stain for actin and are responsible for the elongated cell phenotype. Withdrawal of IL-3 dissolves ruffled protrusions and converts the cell phenotype to round. Flow cytometric analysis of the cell shape showed that an inactive analog of Rac1 but not inactive RhoA or inactive cdc42 rounds the cells in the presence of IL-3. Constitutively activated Rac1 restores the elongated cell phenotype to IL-3-starved cells. We conclude that the activity of Rac1 is necessary and sufficient for the IL-3-induced assembly of membrane ruffles. Similar to the IL-3 withdrawal, phorbol 12-myristate 13-acetate (PMA) dissolves actin-formed membrane ruffles and rounds the cells in the presence of IL-3. Flow cytometric analysis of the cell shape demonstrated that in the presence of IL-3 the PMA-induced cell rounding cannot be abolished by constitutively active Rac1 but can be imitated by inactive Rac1. These data indicate that PMA disrupts the IL-3 pathway downstream of Rac1. Cells rounded by PMA return to the elongated phenotype concomitantly with PKC depletion. PMA-induced cell rounding can be reversed by the PKC-specific inhibitor GF109203X. Experiments with overexpression in Baf3 of individual PKC isoforms and a dominant negative PKC-delta indicate that activation of PKC-delta but not other PKC isoforms is responsible for disruption of membrane ruffles.