Growth-inhibitory activity of lymphoid cell plasma membranes. II. Partial characterization of the inhibitor

Microenvironmental influences of apoptosis in vivo and in vitro

The apoptosis program of physiological cell death elicits a range of non-phlogistic homeostatic mechanisms-"recognition, response and removal"-that regulate the microenvironments of normal and diseased tissues via multiple modalities operating over short and long distances. The molecular mechanisms mediate intercellular signaling through direct contact with neighboring cells, release of soluble factors and production of membrane-delimited fragments (apoptotic bodies, blebs and microparticles) that allow for interaction with host cells over long distances. These processes effect the selective recruitment of mononuclear phagocytes and the specific activation of both phagocytic and non-phagocytic cells. While much evidence is available concerning the mechanisms underlying the recognition and responses of phagocytes that culminate in the engulfment and removal of apoptotic cell bodies, relatively little is yet known about the non-phagocytic cellular responses to the apoptosis program. These responses regulate inflammatory and immune cell activation as well as cell fate decisions of proliferation, differentiation and death. Here, we review current knowledge of these processes, considering especially how apoptotic cells condition the microenvironments of normal and malignant tissues. We also discuss how apoptotic cells that persist in the absence of phagocytic clearance exert inhibitory effects over their viable neighbors, paying particular attention to the specific case of cell cultures and highlighting how new cell-corpse-clearance devices-Dead-Cert Nanoparticles-can significantly improve the efficacy of cell cultures through effective removal of non-viable cells in the absence of phagocytes in vitro.

Cell death in the neighbourhood: direct microenvironmental effects of apoptosis in normal and neoplastic tissues

Here we consider the impact of the physiological cell-death programme on normal tissue homeostasis and on disease pathogenesis, with particular reference to evolution and progression of neoplasia. We seek to describe the direct contributions played by apoptosis in creating the microenvironments of normal and malignant tissues and to discuss the molecular mechanisms underlying the elements of the '3Rs' that define the meaning of apoptosis: recognition, response, and removal. Apoptotic cells elicit responses in other cell types-both phagocytic and non-phagocytic-through short- and long-range signalling modes that range from direct contact to intercellular communication via membrane-bound microparticles. Such cellular responses include migration, proliferation, and differentiation, as well as production of immunomodulatory and anti-inflammatory mediators together with, in the case of phagocytes, engulfment, and breakdown of apoptotic cells. In normal tissues, the removal of apoptotic cells is rapid and typically non-phlogistic. We discuss the importance of this clearance process in tissue homeostasis and the consequences of its failure in disease pathogenesis. Using the typical cell culture environment in vitro as an illustrative example in which apoptosis occurs commonly in the absence of the removal mechanisms, we also discuss the inhibitory effects of persistent apoptotic cells on their otherwise viable neighbours. Since apoptosis is a common and sustained event in high-grade malignancies, we hypothesize on its purposeful role in conditioning the tumour microenvironment. We propose that apoptosis subserves several pro-tumour functions-trophic, anti-inflammatory, and immunomodulatory-and we identify strategies targeting host responses to apoptotic cells as promising modes of future therapies that could be applied to multiple cancer types in which tumour-cell apoptosis is active.

Inhibitory effects of persistent apoptotic cells on monoclonal antibody production in vitro: simple removal of non-viable cells improves antibody productivity by hybridoma cells in culture

Cells undergoing apoptosis in vivo are rapidly detected and cleared by phagocytes. Swift recognition and removal of apoptotic cells is important for normal tissue homeostasis and failure in the underlying clearance mechanisms has pathological consequences associated with inflammatory and auto-immune diseases. Cell cultures in vitro usually lack the capacity for removal of non-viable cells because of the absence of phagocytes and, as such, fail to emulate the healthy in vivo micro-environment from which dead cells are absent. While a key objective in cell culture is to maintain viability at maximal levels, cell death is unavoidable and non-viable cells frequently contaminate cultures in significant numbers. Here we show that the presence of apoptotic cells in monoclonal antibody-producing hybridoma cultures has markedly detrimental effects on antibody productivity. Removal of apoptotic hybridoma cells by macrophages at the time of seeding resulted in 100% improved antibody productivity that was, surprisingly to us, most pronounced late on in the cultures. Furthermore, we were able to recapitulate this effect using novel super-paramagnetic Dead-Cert Nanoparticles to remove non-viable cells simply and effectively at culture seeding. These results (1) provide direct evidence that apoptotic cells have a profound influence on their non-phagocytic neighbors in culture and (2) demonstrate the effectiveness of a simple dead-cell removal strategy for improving antibody manufacture in vitro.

Inhibition of induced lymphocyte proliferation by lipid and protein components of the syncytiotrophoblast plasma membrane

PROBLEM

The aim of this work was to define the respective responsibilities of the lipid and protein components of syncytiotrophoblast plasma membranes on the inhibition of lymphocyte proliferation induced in vitro.

METHOD

A fractionation method using octyl-beta-D-glucopyranoside enabled lipoprotein, lipid, and protein fractions to be isolated from the membrane.

RESULTS

The lipid fraction was shown nonspecifically to inhibit lymphocyte proliferation, to a lower extent compared with the native membrane. Alternatively, the protein fraction used as a proteoliposome contained the totality of the cytostatic effect of the native fraction.

CONCLUSION

These results are discussed generally in the context of the immunoregulatory role of membrane lipids and proteins and in relation to the local properties of syncytiotrophoblast plasma membrane components in fetal graft tolerance.

Expression of a negative regulator of human erythropoiesis by fluidized lymphocyte plasma membranes

Regulation of hematopoiesis by paracrine molecules occurs in vitro. In some cases, hematopoietic paracrine factors have been localized to the plasma membrane of accessory cells. We have purified a unique integral membrane glycoprotein from normal human B cells that functions in vitro as a paracrine factor whose activity is directed toward erythroid progenitor cells. This factor is also spontaneously exfoliated from the cell surface as a component of extracellular vesicles. Analysis of the lipid and protein compositions and membrane lipid order of these extracellular vesicles reveals them to be biochemically distinct and more fluid than their parent membranes. Evidence in nonhematopoietic culture systems indicates that cell membrane function may be altered by modifying membrane fluidity. In an effort to accelerate growth factor release, plasma membranes of B cells were fluidized by incubation with an emulsion of Liposin II, phosphatidylcholine, and phosphatidylethanolamine. Fluidity assessed by steady-state fluorescence polarization was reduced in lipid-treated cells. Exfoliation was 3-4-fold higher from lipid-treated cells relative to untreated cells. Unexpectedly, a negative signal for burst-forming unit-erythroid (BFU-E) proliferation was expressed in membranes, in shed extracellular vesicles, and in supernatants of medium conditioned by the fluidized cells. Purification of the inhibitor is under way. The data are consistent with the hypothesis that accessory cell plasma membranes may positively or negatively regulate erythroid differentiation, depending upon the exchange of cholesterol and phospholipids between plasma membrane and ambient lipid pools.

A potent DNA synthesis inhibitor expressed by the immortal cell line SUSM-1

We have previously reported the production of DNA synthesis inhibitor proteins by both quiescent and senescent human diploid fibroblasts. Young, proliferating fibroblasts do not produce such inhibitors, but are capable of responding to either the quiescent or senescent cell DNA synthesis inhibitors. Recently, we have analyzed the immortal cell line SUSM-1 (derived from normal liver fibroblasts following exposure to carcinogen) for inhibitory activity. We have found that SUSM-1 cells produce a factor capable of inhibiting DNA synthesis in young fibroblasts. Crude extracts prepared from SUSM-1 cells inhibit DNA synthesis in a dose-dependent manner at concentrations 10-fold lower than those of either senescent or quiescent fibroblast cell extracts. SUSM-1 cells are incapable of responding to the inhibitor they produce, as are three other immortal human cell lines tested. One immortal cell line, HeLa, does respond to the SUSM-1 inhibitor, though to a lesser degree than observed with normal young fibroblasts. One hypothesis is that the DNA synthesis inhibitor protein(s) of senescent cells plays a role in determining the finite in vitro life span of normal cells. The results reported here suggest that SUSM-1 cells may have escaped senescence through loss of a receptor or cofactor for the inhibitor protein(s).

Cell density dependent morphological changes in adult rat hepatocytes during primary culture

In order to gain morphological insights about the cell density dependency, hepatocytes cultured at a low cell density (less than about 0.1 X 10(5) nuclei (cm2)-1) and at a high cell density (greater than about 1 X 10(5) nuclei (cm2)-1) were examined ultrastructurally 24 h after plating (just prior to the beginning of DNA synthesis). The results were as follows: (i) glycogen rosettes disappeared completely in low density culture as compared with sections from an intact liver. In contrast, glycogen rosettes were still present in high density culture. (ii) Polysomes seemed increased in low density culture in comparison with those seen in sections from an intact liver and from the high density culture. (iii) In low density culture, the shape of mitochondria deviated from that of hepatocytes in an intact liver and the mitochondria often lost a characteristic close contact with rough endoplasmic reticulum (rough ER). (iv) In low density culture, bundles of filamentous structure were detected, which were not found in an intact liver or high density culture. The following features were found only in high density culture; (v) numerous villous cytoplasmic protrusions developed along the area facing adjacent cells, and seemed to intertwine with each other, and (vi) between the hepatocytes, only abortive junctions were found. These results indicate that the hepatocytes cultured at a low density express most of the characteristics of the hepatocytes in a regenerating liver and the features of the cells cultured at a high density are very similar to those of the hepatocytes in sections from an intact liver.

B cell-stimulating activity of lymphoid cell membrane fractions

We had previously found that a mutagenized subline of the mouse thymoma EL4 very efficiently stimulates B cells via direct cell-cell contact, thereby inducing the responsiveness of B cells to cytokines. In the present study, we investigated whether this effect could also be mediated by plasma membranes of EL4 (and other) cells. By equilibrium centrifugation of cell homogenates, four cell membrane fractions of different densities were obtained. These were tested for (a) stimulation of B cell proliferation in conjunction with EL4 supernatant as source of cytokines, and (b) enhancement of B cell proliferation at suboptimal concentration of lipopolysaccharide. It turned out that all membrane fractions from a variety of T lineage cells (mutant EL4, parent EL4, BW5147, P198 thymomas, normal T cells) and B lineage cells (BCL1 lymphoma, X63Ag8 cytoplasma, normal B cells) exhibited similar B cell stimulating activity in both assays. Interleukin 1 activity was not detected in the membrane fractions. Heat treatment abolished all activity showing that protein at least was involved. Either protease treatment or extraction with detergent abolished the activity of subcellular fractions rich in intracellular membranes but not that of fractions most enriched in surface membranes. Finally, erythrocyte membranes also displayed B cell-stimulating activity sensitive to protease and detergent extraction. In contrast, and in confirmation of a previous study, liver cell membrane was inhibitory in the B cell proliferation assay with lipopolysaccharide. In conclusion, the effects of cell membranes did not reflect the unique activity of intact mutant EL4 cells. However, with respect to our data it is conceivable that membrane proteins with relatively nonspecific activity and wide distribution among lymphoid cells could play a role in T cell help together with molecules specialized in cell adhesion and cell triggering.

Membrane oligosaccharides: structure and function during differentiation

Recent results gathered by normal light microscopy, immunocytochemistry, fluorescent-analog cytochemistry, and electron microscopy have allowed an improved interpretation of ameboid movement and related phenomena. 1. The contractile system responsible in Amoeba proteus for the generation of motive force for protoplasmic streaming and a large variety of dynamic activities is represented mainly by a thin cortical filament layer at the cytoplasmic face of the cell membrane (Fig. 18I). During normal locomotion this layer exhibits a distinct structural and physiological polarity with three different zones: a zone of reformation at the front (A), a zone of contraction in the intermediate cell region (B), and a zone of destruction at the uroid (C). 2. Two types of filaments participate in the formation of the cortical layer: (1) randomly distributed thin (actin) filaments exhibiting a parallel orientation in the anterior (Fc1) and a disordered arrangement in the intermediate and posterior cell region (Fc2; see also Fig. 17b), and (2) thick (myosin) filaments in close association with F-actin and mostly restricted to the intermediate and posterior cell region (Fc2). 3. The internal hydraulic pressure generated by localized active contraction of the cortical layer is transmitted to the endoplasm via the cell membrane and converted into directed streaming by a gel-sol gradient of decreasing viscosity between the uroid and the front. Calcium ions, ATP, and regulative proteins (profilin and a kinase) play an essential role in controlling both the interaction of actin and myosin and the sol-gel state of the cytoplasmic matrix. 4. Any alterations externally induced in the polarity of the cortical filament system by chemical or physical stimulation and inhibition cause immobilization of the amebas (Fig. 18II) with characteristic changes in (1) cell shape (spherulation and cell flattening), (2) membrane dynamics (cytotic and cytokinetic activities), and (3) cytoplasmic organization (hyalogranuloplasmic separation). pseudopodial tip (Fig. 18III, b----c, d----e), (3) destruction of the old layer at the hyalogranuloplasmic border (Fig. 18III, c,e), and (4) alternate solation (Fig. 18III, b and d) and gelation (Fig. 18III, c and e) of the hyaloplasm between the layer and the plasma membrane. The retraction of pseudopodia is accomplished by a local contraction of the cortical layer in conjunction with a simultaneous gel-sol transformation of the ectoplasmic cylinder. 6. The expression of a rather complex cytoskeleton which is composed not only of microfilaments and associated proteins, but also of intermediate- and microtubularlike structures has to be considered in future

Selective induction of tyrosine hydroxylase by cell-cell contact in bovine adrenal chromaffin cells is mimicked by plasma membranes

As a first step towards the identification and purification of the molecule(s) that are involved in cell contact-mediated tyrosine hydroxylase (TH) induction in cultures of bovine adrenal chromaffin cells, we have prepared plasma membranes (PM) from bovine adrenal medulla and tested their ability to mimick cell contact-mediated TH induction in low density chromaffin cultures. PM indeed induced TH in a manner similar to that observed in high density cultures. The maximal TH induction reached by PM corresponded to 69% of that of high density cultures, and half-maximal TH induction was obtained with 12 micrograms of PM per ml of medium. The induction of TH by PM was blocked by alpha-amanitin as observed in high density cultures. Since acetylcholinesterase was neither induced in high density nor in PM-treated low density cultures, an induction of TH as a result of a general increase in protein synthesis was excluded. The cell contact molecule(s) appear to be intrinsic membrane proteins. They were not removed by high or low salt extraction, but solubilized by 50 mM octylglucoside. They were resistant to 0.1% trypsin and heat denaturation but inactivated by 0.01% chymotrypsin. PM isolated from the adrenal cortex, kidney, and liver also induced TH in low density chromaffin cell cultures, although to a smaller extent than PM of the adrenal medulla. In contrast, muscle and erythrocyte PM were inactive. This shows that the cell contact molecule(s) are not restricted to the adrenal medulla, but are also present in some other but not all tissues.

Specific inhibition of endothelial cell proliferation by isolated endothelial plasma membranes

Cultures of human vascular endothelial cells were used to study the phenomenon of density-dependent inhibition of cell growth. Endothelial cells were disrupted by nitrogen cavitation, and a plasma membrane-enriched fraction was prepared by differential centrifugation followed in some cases by sucrose density gradient fractionation. Membrane suspension was added to low-density early-passage endothelial cultures grown in microwells. Hemocytometer cell counts and 6 hr 3H-thymidine pulses were performed in triplicate wells at varying intervals. Plasma membranes suppressed cell proliferation in a reversible, dose-dependent fashion. Increasing the ambient concentration of endothelial cell growth factor did not alter the inhibitory effect. The antiproliferative effect was sensitive to heat and trypsin and to incubation with 0.1 M sodium carbonate, pH 11.5. Membrane vesicles selectively derived from the apical cell surface also suppressed proliferation. This phenomenon showed at least some specificity for cell type and species in both human and bovine models. Therefore, cell-cell contact is capable of regulating endothelial cell proliferation in vitro despite the presence of available growth surfaces and of optimally supportive culture medium.

Inhibition of lymphocyte proliferation by detergent-solubilized mouse liver membranes

The role of phenomena analogous to fibroblast contact inhibition in lymphocyte growth regulation is controversial, although it is clear that direct cell-cell contact is vital to immunoregulation and accessory cell function. An extract of mouse liver plasma membrane proteins, referred to as suppressive liver extract (SLE), that suppresses the growth of 3T3 fibroblasts also inhibited the mitogen-induced proliferation of murine lymphocytes. A dose of 20 micrograms/ml SLE was less than 95% suppressive of proliferation in both mouse T and mouse B cells treated with a variety of mitogens. B cell growth factor, while increasing DNA synthesis overall in mitogen-stimulated B cells, did not change the extent of SLE suppression, which suggests that the SLE does not interfere with lymphocyte-growth factor interactions. In exploring a sequence of B cell activation events, we discovered that SLE had no effect on the early activation event of increased phosphatidylinositol turnover. Blastogenesis, however, was inhibited in mitogen-stimulated, SLE-treated B cells. The maximum suppressive effect was observed if the SLE was added within 8-12 h of the mitogenic stimulus. SLE did not affect the viability of cells in culture. These results point to a possible unity of regulatory mechanisms between contact inhibition in fibroblasts and the processes of immunoregulation.

Growth-inhibitory activity of lymphoid cell plasma membranes. I. Inhibition of lymphocyte and lymphoid tumor cell growth

Membranes isolated from normal spleen cells or lymphoid tumor cells were found to inhibit in vitro growth of several murine tumor cell lines including a B cell hybridoma, a thymoma, and a mastocytoma. 50% inhibition occurred at membrane protein concentrations of 60-100 micrograms/ml. A similar concentration dependence was found for inhibition of [3H]-thymidine incorporation by tumor cells and for the lipopolysaccharide-induced mitogenic response of normal spleen cells. The inhibitory activity co-purified with the plasma membrane upon fractionation of crude membranes. Membrane solubilization with deoxycholate followed by dialysis to remove the detergent gave good recovery of inhibitory activity in the resulting reconstituted membranes. Membrane-mediated growth inhibition resulted from a decreased rate of proliferation and not from increased cell death. A toxic effect of the membranes was further ruled out by the finding that increasing the fetal calf serum content of the medium could substantially reverse the growth inhibition. Thus, the plasma membrane of lymphoid cells contains a component that can slow or stop the growth of cells in culture. This membrane component may have a role in cell contact-mediated regulation of growth.