Modulation of tumor cell susceptibility to cytokine-induced cell death by hormones, growth factors, and cell density.

The mechanisms controlling "spontaneous" cellular death rates in normal and tumorigenic tissues are largely unknown. An important parameter in this respect is the susceptibility of the target cell to induction of the lytic pathway by appropriate signals. In the present article it is demonstrated in a serum-free in vitro system that the susceptibility of human tumor cells (TC) to induction of lysis by cytokine signals generated during interaction of TC with elutriated human monocytes (MO) is a highly dynamic parameter subject to modulation by hormones, growth factors, and tumor cell density. It was found that growth stimulatory signals such as insulin, and especially epidermal growth factor (EGF), increase lytic susceptibility, whereas hydrocortisone, which does not exert significant growth modulatory effects in these examples, protects TC against the induction of lysis. Increasing TC density above confluence dramatically enhances lytic susceptibility, suggesting interactions between TC to be involved in the induction of their death. In conjunction with previous data demonstrating the insusceptibility of TC, which are forced out of the cell cycle into the quiescent state (G0), the hypothesis is put forward that growth stimulatory factors increase a TC's lytic susceptibility by preventing its transit from G1 to G0 in response to growth inhibitory signals generated during MO/TC interaction. The data support the concept that TC susceptibility to the induction of cell death is a consequence of simultaneously activated growth stimulatory and growth inhibitory signalling pathways.     

LIRs/ILTs/MIRs, inhibitory and stimulatory Ig-superfamily receptors expressed in myeloid and lymphoid cells

Cells exhibit a complex network of inhibitory and stimulatory signaling pathways, which interact with each other to maintain an homeostatic balance and modulate cellular responses to external stimuli. During most of the 1980s, a great effort was put into the characterization of stimulatory cell surface receptors for cytokines and growth factors. In the last decade, a large number of inhibitory receptors have been identified and it has become apparent that inhibitory signaling pathways are subject to intricate regulatory mechanisms. Inhibitory and stimulatory signaling pathways work in concert with each other to establish activation thresholds and provide sensitive tuning mechanisms that help control cellular responses. LIRs/ILTs/MIRs are a novel family of inhibitory and stimulatory receptors expressed both in myeloid and lymphoid cells. They contain two or four immunoglobulin-like domains in the extracellular region and their cytoplasmic domains are either very short and without any signaling motifs or are long and contain a variable number of immunoreceptor tyrosine-based inhibition motifs (ITIMs). LIRs within the first group send stimulatory signals by association with the FcR common gamma chain and LIRs within the second group deliver inhibitory signals by association with the protein tyrosine phosphatase SHP-1. This review summarizes our current knowledge on the LIRs, their ligands, and biological functions.     

From growth arrest to growth suppression.

Since the introduction of the cell cycle concept two approaches to study growth regulation of cells have been proposed. One claims that cells are naturally quiescent, requiring a stimulatory encouter with growth factors for induction of cell division. The other considers cellular multiplication as the natural steady-state; cessation of multiplication is thus a restriction imposed on the system. In the latter case emphasis is mainly on the signals involved in arrest of multiplication. This Prospect focuses on specific events occurring in mammalian cells at growth arrest, senescence, and terminal differentiation, specifically emphasizing the growth inhibitory factors, tumor suppressor genes, and other signals for growth suppression.     

SLAM and CD31: signaling molecules involved in cytokine secretion during the development of innate and adaptive immune responses

Immune cells are modulated through the crosslinking of receptors named "immunoreceptors". Ligation of immunoreceptors by their ligands induces a tyrosine-phosphorylation signal that is essential for cell activation or inhibition. Physiologically, immunoreceptor triggering is not enough for cell activation, and stimulation of co-receptors is necessary for antigen-evoked cytokine production. Thus, signal transduction pathways mediated by proteins that regulate cytokine secretion are critical to achieve an effective immune response of the host, where the balance between positive and negative signaling allows effective immune responses, preventing tolerance and autoimmunity. This review deals with recent studies based on the role of the receptor signaling lymphocytic activation molecule (SLAM), a signaling protein that modulates cytokine secretion by immune cells, and the transmembrane glycoprotein CD31, which plays multiple roles in cellular signaling events by modulating the balance between inhibitory and stimulatory signals to immune cells. Recent studies have shed light on the ability of these molecules to transmit different signals that regulate the ability of innate and adaptive immune cells to synthesize stimulatory and inhibitory cytokines.     

Activation or tolerance of natural killer cells is modulated by ligand quality in a nonmonotonic manner

Natural killer (NK) cells extend important immune resistance in vertebrates by lysing infected and tumor cells. A fine balance between opposing signals generated by a diverse set of stimulatory and inhibitory NK-cell receptors determines the fate of target cells interacting with the NK cells. We have developed a mathematical model involving membrane proximal initial signaling events that provides novel mechanistic insights into how activation of NK cells is modulated by the half-life of receptor-ligand interaction and ligand concentrations. We show that strong stimulatory ligands produce digital activation, whereas weaker stimulatory ligands can mediate inhibition by strengthening the signals generated by inhibitory ligands, as indicated in experiments in knockout mice. We find under certain conditions, counterintuitively, inhibitory receptors can help mediate activation instead of inhibition. Mechanistic insights gained from NK-cell signaling can facilitate understanding of complex signaling responses that occur due to cross talk between dueling signaling pathways in other cell types.     

Inhibition of transformed T cell growth in vitro by monoclonal antibodies directed against distinct activating molecules

Stimulatory of antigen-specific murine T cell hybridomas with the appropriate antigen has been shown to cause lymphokine secretion and inhibition of spontaneous cell growth. In this study, the effect of cellular activation on the growth of transformed T cells, of known or unknown antigen specificity, was explored with stimulatory monoclonal antibodies (mAb) that recognize nonclonally distributed T cell surface molecules. Anti-CD3 antibodies stimulated interleukin 2 (IL-2) secretion while they inhibited murine and human T cell tumor growth in vitro. Both responses required external cross-linking of the anti-CD3 antibodies. Activation via two molecules that are not physically associated with the T cell antigen receptor, Thy-1 and Ly-6, also inhibited transformed T cell growth while inducing IL-2 secretion. Notably, an anti-Thy-1 mAb that did not cause the transformed T cells to secrete lymphokines failed to affect their growth, and in fact blocked the growth inhibition induced by the stimulatory mAb. Regardless of which stimulating mAb was used, IL-2 production and cell growth were inversely proportional, manifesting similar antibody dose-response curves. Activation of a T cell hybridoma with stimulatory mAb resulted in rapid lysis, as evidenced by the release of 51Cr and lactate dehydrogenase. Cell cycle analysis demonstrated that cellular activation was accompanied by a cell cycle block between the G1 and S phases, and probably a slowing of the transit of cells already in S. These results demonstrate that the growth of a spectrum of neoplastic T cells, murine and human, can be inhibited by what are normally growth-promoting signals for non-transformed T cells.     

Signal transduction via platelet-derived growth factor receptors

Platelet-derived growth factor (PDGF) exerts its stimulatory effects on cell growth and motility by binding to two related protein tyrosine kinase receptors. Ligand binding induces receptor dimerization and autophosphorylation, allowing binding and activation of cytoplasmic SH2-domain containing signal transduction molecules. Thereby, a number of different signaling pathways are initiated leading to cell growth, actin reorganization migration and differentiation. Recent observations suggest that extensive cross-talk occurs between different signaling pathways, and that stimulatory signals are modulated by inhibitory signals arising in parallel.     

Communication between white cells and the abnormalities of this in leukemia.

The production of white blood cells is mediated by cellular communication. Proliferation and differentiation of granulocytic and monocytic progenitor and immature cells have been studied in detail and are regulated by stimulatory and inhibitory molecules produced and released from the progeny of the progenitor cells. The resultant interactions between cells and cell-derived molecules suggest operable positive and negative feed-back mechanisms during normal hematopoiesis, and what one sees in the end is the net result of these interactions. The complexities of cellular regulation are partially unravelled by physical separation of the different populations and biochemical analysis of the regulatory molecules. Subpopulations of granulocyte-monocyte progenitors (CFU-c) exist and evidence suggests that they vary in responsiveness to different molecules. Stimulatory molecules are themselves chemically and physically heterogenous and, until recently, believed to have similar biological actions, but this concept must be re-evaluated. Different molecules may activate different subsets of progenitor cells, and there is now a role for substances which enhance the stimulatory interactions. Many studies on normal and leukemic cell responsiveness to stimulation must be re-examined in light of this recent information. Several inhibitory substances operate during normal hematopoiesis. Mature granulocytes, progeny of CFU-c, appear to elaborate at least two inhibitory activities. One activity influences immature, recognizable granulocytes and the other indirectly reduces progenitor cell proliferation by decreasing the production and release of molecules which stimulate CFU-c. In addition, mononuclear phagocytes produce and release E-type prostaglandins in direct response to elevated levels of the stimulatory molecules and E-type prostaglandins counteract increased stimulatory levels by decreasing the sensitivity of CFU-c to stimulators. Much of our present level of sophistication derives from in vitro experimentation and it is apparent that we are only beginning to understand these inter-relationships and their relevance to the in vivo situation. However, these in vitro studies have shed light on the interactions occurring during leukemia. Leukemic cells retain the capacity to respond to normal regulators and must therefore be considered dependent rather than autonomous neoplasms. Abnormalities do exist in leukemic cell interactions: the progenitor cells themselves may be defective and leukemic cells may respond to molecules which normal cells do not. The degree of sensitivity to stimulators and inhibitors will have to be carefully investigated to determine if and what differences may exist between normal and leukemic cells. Normal mature granulocyte derived inhibitory activity is quantitatively deficient in leukemic cells but another inhibitory activity which appears to be specifically present in cells from patients with leukemia and some cases of myelodysplasia is present...     

Identification of a tumor inhibitory factor in rat ascites fluid

A polypeptide which inhibits the growth of human carcinoma cells has been characterized from Novikoff rat ascites fluid. This tumor inhibitory factor co-purified with transforming growth factor activity through acid/ethanol extraction and Bio-Gel chromatography. The two activities were completely separated by reverse phase HPLC. The tumor inhibitory factor is heat stable and requires disulfide bonds for bioactivity. This factor inhibited the anchorage independent growth of the more differentiated human colon carcinoma cell lines but did not affect the less differentiated carcinoma cells. The presence of stimulatory and inhibitory activities in the same extracts suggests that the relative concentrations of these factors may be important in the control of cell growth.     

Dual effects of thymic substance(s) on growth of cultured mammalian cells

Saline extracts from thymus glands of mice, or thymocyte suspensions, had stimulatory and inhibitory influences on the growth of mammalian cells in vitro. The stimulatory effect appeared at high extract concentrations as amounts of Lowry-positive substance, and at high suspension densities. The inhibitory effect was observed at low concentrations of the extract and at low densities of the suspension. The thymus extract not only affected the initiation of cell proliferation but also influenced proliferation of their descendants. The tissue fragments obtained from normal mouse exhibited the inhibitory action and the one from mice irradiated with 700 R showed the stimulatory effect on the colony formation. These facts may suggest that two different substances responsible for affecting cell growth are produced by different types of cells in the thymus. It was also found that the suspension prolonged the generation time of the cells and that calf serum was antagonistic to those dual actions. Moreover, the loss of inhibitory activity with trypsin treatment strongly suggests that the thymic materials contain a protein as an active site.     

Regulation of cell proliferation inhibitory and stimulatory factors diffused by 3T3 cultured cells

The growth rate of normal cells multiplied in vitro decreases as the cell density of the culture increases. Previous results suggested that this density-dependent inhibition of growth in nontransformed cells was due to the diffusion of growth inhibitory substances in the medium of dense cultures. In this paper, we demonstrate that dense cultures of 3T3 cells secrete inhibitory and stimulatory factors. Macromolecules of conditioned medium were fractionated on Biogel P150 and the different fractions were tested on quiescent cultures of 3T3 cells stimulated or not to proliferate by addition of alpha globulin. When target cells were not stimulated to proliferate by addition of exocrine growth factors, we observed the inhibitory activity of a large molecular weight inhibitor (IDF45) and the stimulatory activity of autocrine growth factors (fraction about 35 and 10 K molecular weight), on the incorporation of 14C inosine into nucleotide pool and RNA. However, DNA synthesis was significantly stimulated with fraction 10 K only. This discrepancy between the stimulation of RNA and DNA synthesis may be explained by the presence, simultaneously, of inhibitory and stimulatory factors in fraction 35 and 10 K molecular weight. The presence of inhibitory factor was demonstrated when the fractions were tested on target cells stimulated to proliferate by alpha globulin addition and labeled with 14C thymidine. In these conditions, the stimulatory activity of autocrine growth factors was not observable, and only the inhibitory activity on DNA synthesis of fractions 35 and 10 K appeared. It is tempting to assume that the regulation of in vitro cell proliferation is determined by the balance between these antagonist stimulatory and inhibitory autocrine growth factors.     

Nerve growth factor chromatin receptor and cell surface receptor-regulated growth of melanocytes and nevus cells.

RNA synthesis in melanocytes and nevus cells, and the proliferation of those cells in the presence of nerve growth factor (NGF) and 12-0-tetradecanoyl-phorbol-13-acetate (TPA), were found to correlate with the amount of NGF bound to the chromatin versus the total internalized NGF (n/c NGF = nuclear/cellular ration). In nevus cells and in melanocytes of the early passages (n/c NGF = 0.16-0.18), NGF slightly activated RNA synthesis but was without any effect on cell growth. At passage 5-6 of melanocytes (n/c NGF = 0.88), NGF inhibited RNA synthesis, which led to inhibition of cell growth. Removal of TPA from the culture of nevus cells resulted in increased n/c NGF ratio and in a switch from activatory to inhibitory action of NGF. The possibility that the cell surface receptor mediated the stimulatory effect of NGF and may antagonize the chromatin receptor-mediated inhibitory effect of NGF of melanocyte and nevus cell growth is discussed.     

Interplay between proliferation and differentiation within the myogenic lineage.

In muscle cells, as in a variety of cell types, proliferation and differentiation are mutually exclusive events controlled by a balance of opposing cellular signals. Members of the MyoD family of muscle-specific helix-loop-helix proteins which, in collaboration with ubiquitous factors, activate muscle differentiation and inhibit cell proliferation function at the nexus of the cellular circuits that control proliferation and differentiation of muscle cells. The activities of these myogenic regulators are negatively regulated by peptide growth factors and activated oncogenes whose products transmit growth signals from the membrane to the nucleus. Recent studies have revealed multiple mechanisms through which intracellular growth factor signals may interfere with the functions of the myogenic regulators. When expressed at high levels, members of the MyoD family can override mitogenic signals and can cause growth arrest independent of their effects on differentiation. The ability of these myogenic regulators to inhibit proliferation of normal as well as transformed cells from multiple lineages suggests that they interact with conserved components of the cellular machinery involved in cell cycle progression and that similar types of regulatory factors participate in differentiation and cell cycle control in diverse cell types.     

Identification and characterization of plasma membrane proteins that bind to microtubules in pollen tubes and generative cells of tobacco

The organization and function of microtubules in plant cells are important in many developmental stages. Connections between microtubules and the endomembrane system of plant cells have been discovered by microscopy, but the molecular characteristics of these relationships are mostly unknown except for a few cases. Using two antibodies raised against microtubule-associated proteins (MAPs) from maize, we have identified two polypeptides that share properties of the MAP family in the pollen tube of Nicotiana tabacum. The two polypeptides (with an apparent Mr of 161 and 90 kDa) bind efficiently to animal and plant microtubules and are found in association with the cellular membranes of the pollen tube, from which they can be solubilized with a zwitterionic detergent. One of these proteins has been purified and shown to promote the assembly of tubulin and, to a lesser extent, the bundling of microtubules. Subcellular fractionation indicated that the two proteins are associated with the plasma membrane compartment. The two proteins are found to co-localize in situ with cortical microtubules in the vegetative cytoplasm of tobacco pollen tubes; co-localization is also evident in the generative cell. According to these data, both the 161 and 90 kDa polypeptides are likely to mediate the interactions between the plasma membrane and microtubules in pollen tubes. In addition, functional data indicate that these MAP-like proteins take part in the process of microtubule assembly and reorganization occurring during cell growth. The evidence that both proteins associate with different cellular compartments also suggests a broad-spectrum role in mediating the dynamic relationships between microtubules and plant cell membranes.     

自然杀伤细胞受体及其配体表达的转录和表观遗传调控

自然杀伤(natural killer cell,NK)细胞受体及其配体在NK细胞发挥抗病毒、抗肿瘤和免疫调节作用中起重要作用.NK细胞功能的发挥取决于NK细胞受体及其配体的表达水平和其所传递信号的综合.病毒、肿瘤和热休克等刺激可以通过激活相应的转录调节因子,提高启动子活性而上调NKG2家族受体及其配体的表达,而启动子区DNA的甲基化状态、组蛋白的乙酰化和甲基化等表观遗传调控,在NK细胞受体及其配体的表达方面亦起重要作用,并决定NK细胞受体的克隆性分布.深入探讨NK细胞受体及其配体的表达调控机制,将为提高NK.细胞抗肿瘤和抗感染疗效提供新的策略.     

Integrin activation by regulated dimerization and oligomerization of platelet endothelial cell adhesion molecule (PECAM)-1 from within the cell

Platelet endothelial cell adhesion molecule (PECAM)-1 is a 130-kD transmembrane glycoprotein having six Ig homology domains within its extracellular domain and an immunoreceptor tyrosine-based inhibitory motif within its cytoplasmic domain. Previous studies have shown that addition of bivalent anti-PECAM-1 mAbs to the surface of T cells, natural killer cells, neutrophils, or platelets result in increased cell adhesion to immobilized integrin ligands. However, the mechanism by which this occurs is not clear, and it is possible that anti-PECAM-1 mAbs elicit this effect by simply sequestering PECAM-1, via antibody-induced patching and capping, away from stimulatory receptors that it normally regulates. To determine whether dimerization or oligomerization of PECAM-1 directly initiates signal transduction pathways that affect integrin function in an antibody-independent manner, stable human embryonic kidney-293 cell lines were produced that expressed chimeric PECAM-1 cDNAs containing one or two FK506-binding protein (FKBP) domains at their COOH terminus. Controlled dimerization initiated by addition of the bivalent, membrane-permeable FKBP dimerizer, AP1510, nearly doubled homophilic binding capacity, whereas AP1510-induced oligomers favored cis PECAM-1/PECAM-1 associations within the plane of the plasma membrane at the expense of trans homophilic adhesion. Importantly, AP1510-induced oligomerization resulted in a marked increase in both adherence and spreading of PECAM/FKBP-2-transfected cells on immobilized fibronectin, a reaction that was mediated by the integrin alpha(5)beta(1). These data demonstrate that signals required for integrin activation can be elicited by clustering of PECAM-1 from inside the cell, and suggest that a dynamic equilibrium between PECAM-1 monomers, dimers, and oligomers may control cellular activation signals that influence the adhesive properties of vascular cells that express this novel member of the immunoreceptor tyrosine-based inhibitory motif family of regulatory receptors.