Cytokine cross-talk between phagocytic cells and lymphocytes: Relevance for differentiation/activation of phagocytic cells and regulation of adaptive immunity

Cytokines represent one of the most important elements in the communication among different cell types. They play an increasingly better understood role in the communication among hematopoietic cells and in particular in the reciprocal regulation of effector cell types of innate or natural resistance (phagocytic cells and Natural Killer (NK) cells) and those of adaptive immunity (T and B lymphocytes). Lymphocytes produce several cytokines with either stimulatory (e.g., colony stimulatory factor) or suppressive (e.g., tumor necrosis factors and interferons) effects on proliferation of early hematopoietic cells. Many of these cytokines, alone or acting in synergistic combinations, also have a differentiation-inducing ability on immature myeloid cells and act as powerful potentiators of the cellular functions of terminally differentiated phagocytic cells. The communication between lymphocytes and phagocytic cells is not unidirectional, as phagocytic cells produce factors that regulate lymphocyte activation. In addition to their role as antigen presenting cells expressing costimulatory accessory molecules and secreting cytokines (e.g., IL-1, IL-6, TNF), phagocytic cells have been recently shown to produce Natural Killer cell Stimulatory Factor (NKSF/IL-12). IL-12 is a heterodimeric cytokine with important modulatory functions on cytotoxicity of NK and T cells, lymphocyte proliferation, lymphokine production, and development of T helper cell subsets. These communications between phagocytic cells and lymphocytes are further regulated by negative and positive feedback mechanisms that contribute to maintain the homeostasis of the system in physiologic conditions and to govern the changes in this equilibrium needed for the response to infectious or other foreign agents.     

Interaction of diphtheria toxin fragment A and of elongation factor 2 with Cibacron blue

Diphtheria toxin fragment A interacts with Cibacron blue in solution, although it is not retained by blue Sepharose columns. Difference spectral titration of fragment A with the dye gives a dissociation constant of the order of 10^–5 M and a 11 stoichiometry for the complex. In equilibrium dialysis experiments Cibacron blue behaves as a competitive inhibitor of the binding of NAD to diphtheria toxin fragment A. The dye inhibits in a non-competitive way the fragment A-catalysed transfer of ADP-ribose from NAD to elongation factor 2 (EF2). By affinity chromatography on blue Sepharose a binding of EF2 and of ADP-ribosyl-EF2 with the dye is also demonstrated. GDP, GTP and GDP(CH₂)P are able to displace EF2 from blue Sepharose.     

Characterization of a concanavalin A supernatant-derived idiotype-specific T helper cell factor

We have previously demonstrated the requirement of two T helper (Th) populations for the expression of plaque-forming cells (PFC) that bear the dominant cross-reactive idiotype (CRI) associated with the phenyltrimethylammonium (TMA) response (1). In addition to the classic major histocompatibility complex-restricted Th cell, the response was also dependent upon the so-called second order Th2 population, which binds to idiotypic determinants, is carrier specific, but does not require hapten linked to carrier for function. This cell type can be replaced by supernatant (Sn) media from concanavalin A (Con A)-stimulated naive spleen cells. This report involves the study of the Con A Sn derived factor(s) responsible for the expression of CRI bearing PFC populations. When the Brucella abortus (BA)-trinitrophenol (TNP) conjugated antigen is added to TNP-ovalbumin-primed A/J-derived spleen cells in culture, anti-TNP PFC are generated of which only less than or equal to 5% bear the CRI normally associated with anti-TMA antibodies. Upon addition of Con A Sn, the total number of generated anti-TNP PFC doubles, whereas the percentage and number of CRI+ PFC increases approximately eightfold to 10-fold. The factor(s) responsible for this activity are T cell derived, bear Jk serologic determinants, and can be detected in the Sn as early as 4 hr after Con A stimulation. The material appears to be late acting, because it can augment the CRI+ anti-TNP response when added as late as 24 hr before termination of the cultures. In addition, the factor(s) can be bound to and eluted from CRI+ anti-TMA and anti-TNP monoclonal antibodies coupled to Sepharose 4B beads, but not from their CRI- counterparts (i.e., CRI- anti-TMA and anti-TNP antibodies), nor from A/J normal mouse immunoglobulin-coupled beads. Most interestingly, the factor(s) also bind to and can be eluted from the TMA ligand coupled to Sepharose 4B, but not from TNP-Sepharose conjugates. All of these results are consistent with the support the contention that the factor(s) is derived from a Th2-like subpopulation. As assayed by standard protocols, the isolated material contains no T cell replacing factor, interleukin 2, or B cell growth factor activity.     

Binding of nicotinamide–adenine dinucleotides to diphtheria toxin

1. Changes in protein fluorescence have been utilized in determining the stoicheiometry and dissociation constants of the complexes of diphtheria toxin with NADH(2), NAD, NADPH(2) and NADP. 2. The binding stoicheiometry is 2moles of NADH(2) and 1mole of NADPH(2)/mole of diphtheria toxin. The binding sites for NADH(2) appear to be equivalent and independent. 3. The toxin shows a higher affinity for the reduced than for the oxidized forms of the nucleotides. 4. Dissociation constants at 0.01I, pH7 and 25 degrees are 0.7x10(-6)m for NADH(2) and 0.45x10(-6)m for NADPH(2). Dissociation constants increase with increasing ionic strength, indicating that the binding is mainly electrostatic. 5. Bound NADH(2) and NADPH(2) may be activated to fluoresce by the transfer of energy from the excited aromatic amino acids of the toxin. Activation and emission spectra of bound and free nucleotides are compared. 6. Since NAD and NADH(2) are cofactors specifically required for the inhibition of protein synthesis by diphtheria toxin, the possible role of toxin-nucleotide complexes is discussed in this regard.     

Antiproliferative effects of heparin on normal and transformed NIH/3T3 fibroblasts.

We studied the effect of heparin on proliferation and signalling in normal NIH/3T3 fibroblasts, and in cells transformed by different oncogenes. Heparin inhibited the proliferation of normal as well as of v-sis and v-erbB transformed fibroblasts in the presence of serum, but failed to inhibit v-erbB-driven proliferation in serum-starved cultures; under these conditions, heparin inhibited by approximately 50% the proliferation of normal and v-sis- transformed cells. Heparin also inhibited PDGF-induced cell proliferation and inositol lipid turnover in v-sis transformants, but it did not affect PDGF mitogenic signalling in NIH/3T3 fibroblasts.     

Regulatory action of prolactin on the in vitro growth of CD34+ve human hemopoietic progenitor cells

The pituitary hormone prolactin (Prl) is known to act as a local regulator of immune cell function, and Prl-binding receptors (Prl-R) have been described to share distinctive features with the members of the newly described cytokine/hemopoietin receptor superfamily. Here we show that the hormone can functionally interact with lineage-specific hemopoietic factors. When highly purified progenitor cells (CD34+ve) were seeded in semisolid methylcellulose cultures in the presence of interleukin (IL)-3, granulocyte-macrophage colony stimulating factor (GM-CSF), and erythropoietin (Epo), a selective enhancing effect of Prl on the formation of colony forming unit-granulocyte (CFU-G) and burst forming unit-erythroid (BFU-E) colonies was observed. The effect of the hormone was plotted as a bell shaped curve, with the optimal response at the supraphysiological concentration of 50 ng/ml. Limiting dilution analysis showed that Prl acted directly on hemopoietic progenitors. This was confirmed by the observation on the CD34+ve cells of Prl-binding sites reacting with the specific monoclonal antibodies (mAbs), U5 and PrR-7A. Immunoprecipitation of the metabolically labeled CD34+ve cells with the PrR-7A mAb revealed a structure of 43 kD under reducing conditions. Analysis of the early events associated with the Prl/Prl-R interaction showed an increased number of cells engaged in DNA and hemoglobin synthesis. Enhanced erythroid differentiation of CD34+ve cells in the presence of Prl was secondary to upmodulation of receptors for the lineage-specific factor Epo. Together these data demonstrate the existence of a functional interplay between Prl. and hemopoietic factors. © 1995 Wiley-Liss, Inc.     

Spontaneous Cell Fusion in Macrophage Cultures Expressing High Levels of the P2Z/P2X7 Receptor

Mouse and human macrophages express a plasma membrane receptor for extracellular ATP named P2Z/P2X₇. This molecule, recently cloned, is endowed with the intriguing property of forming an aqueous pore that allows transmembrane fluxes of hydrophylic molecules of molecular weight below 900. The physiological function of this receptor is unknown. In a previous study we reported experiments suggesting that the P2Z/P2X₇ receptor is involved in the formation of macrophage-derived multinucleated giant cells (MGCs; Falzoni, S., M. Munerati, D. Ferrari, S. Spisani, S. Moretti, and F. Di Virgilio. 1995. J. Clin. Invest. 95:1207– 1216). We have selected several clones of mouse J774 macrophages that are characterized by either high or low expression of the P2Z/P2X₇ receptor and named these clones P2Zhyper or P2Zhypo, respectively. P2Zhyper, but not P2Zhypo, cells grown to confluence in culture spontaneously fuse to form MGCs. As previously shown for human macrophages, fusion is inhibited by the P2Z/P2X₇ blocker oxidized ATP. MGCs die shortly after fusion through a dramatic process of cytoplasmic sepimentation followed by fragmentation. These observations support our previous hypothesis that the P2Z/P2X₇ receptor is involved in macrophage fusion.