Characterization of a spontaneous murine B cell leukemia (BCL1). II. Tumor cell proliferation and IgM secretion after stimulation by LPS.

A spontaneous BALB/c B lymphocyte leukemia could be stimulated in vitro by the polyclonal B cell activator lipopolysaccharide (LPS) and the conditions for activation were studied. Spleen cells or peripheral blood lymphocytes from tumor-bearing animals responded by increased DNA synthesis and the peak of activation occurred earlier than with normal mouse spleen cells. Tumor cells harvested from the spleen, but not from the peripheral blood, could be induced by LPS to secrete IgM. Direct demonstration that the response was due to tumor cell activation and not that of contaminating normal B lymphocytes was provided by karyotype analysis and by immunoprecipitation, which showed the restriction of light chains on secreted IgM molecules to the lambda isotype.     

Co-cultivation of tumorigenic mouse melanoma cells with cells of a non-tumorigenic subclone inhibits plasminogen activator expression by the melanoma cells.

Clone B559 mouse melanoma cells are highly tumorigenic and produce plasminogen activator. Cells of clone C3471, a line obtained by continued growth of B559 cells in medium containing 5-bromodeoxyuridine (1 microgram/ml), have no plasminogen activator and are non-tumorigenic. When B559 cells are co-cultivated with C3471 cells, the ability of B559 cells to activate plasminogen is suppressed. Under these conditions cell fusion occurs. Lack of expression of plasminogen activators is not a consequence of cell fusion, inhibition of cell division or release of soluble inhibitors of either plasminogen activators or plasmin. No inhibitors of plasminogen activators could be demonstrated in association with sub cellular fractions of C3471 cells or with the C-type viral particles released from C3471 cells. Close contact between cells of the two lines is shown to be essential for suppression of plasminogen activation.     

小鼠B7-H4基因的真核表达及其对淋巴细胞增殖的影响

目的构建小鼠B7-H4胞外段的真核表达载体,观察其在体外对淋巴细胞增殖的影响,为深入研究B7-H4在T细胞活化及移植排斥反应中的作用提供实验材料。方法提取小鼠肺、脾脏总RNA,RT-PCR反转录cDNA,以此为模板,扩增B7-H4胞外段基因,将其导入pGEM-T Easy载体,构建TA-mB7-H4质粒。用XBaI和HindIII双酶切后琼脂糖凝胶电泳分析和测序鉴定。将测序证实的mB7-H4酶切后装入MYC-HIS-EGFP-N荧光表达载体中,构建B7-H4-EGFP真核表达载体,转化JM109感受态细菌,提取重组质粒,酶切后琼脂糖凝胶电泳分析和测序鉴定。同时构建control-EGFP载体。应用脂质体法将重组质粒转染CHO细胞,经G418筛选,获得稳定表达B7-H4-EGFP的CHO细胞株,用MTT分析其分别对BALB/c小鼠、C57小鼠淋巴细胞和二者混合淋巴细胞增殖的影响。结果经测序证实,所克隆的小鼠B7-H4 cDNA和构建的重组质粒基因序列正确;转染的CHO细胞能稳定地表达跨膜型重组蛋白B7-H4;表达的B7-H4对淋巴细胞增殖具有明显抑制作用。结论成功构建了B7-H4真核表达系统,能表达有生物学活性的B7-H4分子,为进一步探讨B7-H4在T细胞活化和移植排斥反应中的作用奠定了基础。     

Plasminogen activator from human embryonic kidney cell cultures: Evidence for a proactivator

The nature of the trypsin-activatable plasminogen activator produced by kidney cell cultures (Bernik, M.B. (1973), J. Clin. Invest. 52, 823–834) was investigated using human embryonic kidney (HEK) cell cultures in serum-free medium. Plaminogen activator activity ratios (trypsin-activated/ untreated controls) in HEK cell-conditioned media were maximal (up to 3) during the first week of culture and remained nearly constant at approximately 2 for the next 3–5 weeks, while the total plasminogen activator titer increased in a nearly linear manner. Therefore, coincident with progressive cell dengeration and death, the ratios decreased to near unity due to “spontaneous” activation of the enzyme, which was inhibited in cell-free conditioned media by the pancreatic trypsin inhibitor Kunitz and benzamidine. Since the activator is not inhibited by the trypsin inhibitor, it is concluded that a protease other than the plasminogen activator is responsible for the activation. Increases in the plasminogen activator titers (about 2-fold) were similarly obtained by culturing the cells in medium containing low concentrations (0.05–0.10 μg/ml) of trypsin for up to about 6 weeks. The presence of the trypsin inhibitor in HEK cell cultures decreased the rate of activation, resulting in higher activity ratios (up to 6), and the total plasminogen activator activity was reduced only minimally (<20%), if at all, by the highest concentration of the trypsin inhibitor (100 μg/ml) tested.Affinity chromatography of conditioned media with activity ratios of 1.6–2 separated the plasminogen activator into an active fraction and a fraction which was activated a minimum of 200-fold by trypsin and contained no measurable activity prior to activation. Gel filtration of crude conditioned media or partially purified activator separated the plasminogen activator activity into two peaks; both were trypsin-activatable, and their relative proportions varied with the isolation conditions. The results indicate the occurrence of a proenzyme form of the plasminogen activator in the culture media.     

In vitro immunization. Effect of growth and differentiation factors on antigen-specific B cell activation and production of monoclonal antibodies to autologous antigens and weak immunogens

The antigen-specific activation of murine nonimmunized B lymphocytes subsequently used in hybridization experiments has been investigated by using phylogenetically conserved antigens or autologous immunogens. This in vitro immunization was supported by B cell growth and differentiation factors derived from phorbol myristate acetate-stimulated EL-4 thymoma cells and mixed lymphocyte cultures (MLC). A filter immuno-plaque assay was used to evaluate the effect of different activation procedures on the number of antigen-specific plaque-forming cells (PFC). We first determined the requirement for MLC-derived lymphokines in the in vitro immunization. An optimal number of antigen-specific PFC was obtained when using 33 to 50% of the supernatant from a 48-hr MLC to support the activation. B cell growth and differentiation factors derived from EL-4 cultures were then tested for their abilities to potentiate the number of PFC by using both unseparated spleen cells and highly purified Ig-positive B cells as target cells. The combination of lymphokines found in supernatants from 25% EL-4 thymoma culture and 33% MLC yielded the highest number of PFC when used to support an in vitro immunization. This optimal factor preparation was used to determine the kinetics (4 to 7 days) and the dose response (0.01 to 10 micrograms antigen/ml) of antigen-specific B cell activation before using the immunized splenocytes as parental cells in cell fusion experiments. Mouse albumin and hemoglobin, actin (25 micrograms/ml), RNA polymerase II (5 micrograms/ml), as well as syngeneic mouse serum were used to immunize BALB/c spleen cells in vitro. We obtained antigen-specific PFC by using all of the different immunogens, including syngeneic mouse serum, and the in vitro immunized cells were then used in hybridization experiments. The specific efficiencies of each fusion that made use of cells immunized with mouse albumin, hemoglobin, syngeneic mouse serum, actin, or RNA polymerase II were 12, 31, 33, 52, and 22%, respectively, which illustrated the apparent lack of immune tolerance found when the immunization was performed in culture.     

Plasminogen activator in early embryogenesis: Enzyme production by trophoblast and parietal endoderm

We have surveyed the early stages in the development and differentiation of cultured mouse embryos for plasminogen activator production. This enzyme is first detectable by the sixth equivalent gestation day. Thereafter, cultured blastocysts produce plasminogen activator with a biphasic time course: in the first phase, enzyme secretion rises to a maximum at about the eighth day and then decreases; a second phase, during which more enzyme accumulates, begins somewhat later and continues to at least the fifteenth day.By fractionating the blastocyst into its constituent cell types, we have identified the trophoblast as the cells responsible for the first phase of enzyme synthesis. The pattern of enzyme production by the trophoblast is closely correlated with the invasive period of these cells in vivo and implies that plasminogen activator is involved in embryo implantation. The second phase of plasminogen activator production is due to parietal endoderm, which initiates enzyme synthesis upon differentiation from the inner cell mass. The properties of the parietal endoderm suggest that plasminogen activator may participate in the migration of these cells and/or in the metabolism of Reichert's membrane which accompanies embryo growth.These results are consistent with the concept, developed from work on other cell types, that plasminogen activator may represent a generalized mechanism for tissue remodeling and cell migration.     

Decreased plasminogen activator inhibitor-1 secretion in hypoxic corneal epithelial cells is associated with increased urokinase plasminogen activator activity

The aim of this study was to determine the effects of hypoxia on mRNA levels, cell-associated and -secreted protein concentration, activity, and protein complex formation of urokinase-type plasminogen activator, its receptor, and plasminogen activator inhibitor type-1 in corneal epithelium. Non-transformed human corneal epithelial cells were cultured in 20% oxygen (normoxic conditions) or 2% oxygen (hypoxic conditions) for 1, 3, 5, or 7 days. Relative changes in mRNA levels of plasminogen activator, receptor, and plasminogen activator inhibitor-1 were determined using a cDNA expression array, chemiluminescence, and densitometry. Protein concentrations were determined using enzyme linked immunosorbent assays. Activity assays were also used. Protein complex formation was assayed using cell surface biotinylation, immunoprecipitation, and Western blot analysis. Hypoxic corneal epithelial cells demonstrated no significant differences in plasminogen activator or receptor mRNA. Cell-associated plasminogen activator and membrane-associated receptor protein levels were unchanged. In contrast decreases in mRNA and secreted plasminogen activator inhibitor-1 protein were observed in hypoxic cells. Concurrently, increased cell-associated plasminogen activator activity was observed in hypoxic cells. The formation of plasminogen activator/receptor/plasminogen activator inhibitor-1 complex at the cell surface was not inhibited by hypoxia. However, in hypoxic cells less plasminogen activator inhibitor-1 was associated with receptor. It is concluded that in corneal epithelium cultured in 2% oxygen plasminogen activator inhibitor-1 may be an important regulatory factor of the plasminogen activator system resulting in increased urokinase plasminogen activator activity.     

The production of distinct forms of plasminogen activator by mouse embryonic cells

We have examined cultured parietal endoderm, visceral endoderm, and extraembryonic mesoderm cells from the mouse embryo for production of the protease plasminogen activator. All of these cell types synthesize and secrete the enzyme, but the molecular characteristics of the plasminogen activators differ as defined by the apparent molecular weight in sodium dodecyl sulfate-polyacrylamide gels, the antigenic properties as defined by two antisera to distinct plasminogen activators, and the interaction with an inhibitor present in fetal bovine serum. The parietal endoderm plasminogen activator has a predominant molecular weight of 79,000, is immunoprecipitated and inhibited by an antiserum raised against a human melanoma plasminogen activator, but not by an antiserum against mouse urokinase, and is only partially inhibited by the serum inhibitor. The visceral endoderm and extraembryonic mesoderm plasminogen activators, which are identical by all criteria, have molecular weights of 48,000, are inactivated only by the anti-urokinase antibodies, and are inhibited by an inhibitor in fetal bovine serum. These results establish the presence of at least two different forms of plasminogen activator in the early mouse embryo. The distinctive nature of the enzyme produced by parietal endoderm can be used as a diagnostic marker for this cell type at this stage of development. When F9 teratocarcinoma stem cells are induced to differentiate by retinoic acid and dibutyryl cAMP, they secrete a plasminogen activator of the parietal endoderm type.     

Novel properties of human monocyte plasminogen activator

Human peripheral monocytes stimulated by either muramyl dipeptide [N-acetyl-muramoyl-L-alanyl-D-isoglutamine], bacterial lipopolysaccharide or lymphokine-containing supernatants of human lymphocytes, could be shown to produce and secrete appreciable activities of a 52 000-Mr plasminogen activator. This enzyme was suppressed in control and stimulated cultures by dexamethasone (0.1 microM). Monocyte plasminogen activator could only be assayed under conditions of low ionic strength and had no detectable activity at 0.15 M NaCl. Intracellular enzyme was present as a proenzyme, requiring activation by preincubation with plasminogen containing traces of plasmin, before its activity could be seen on sodium dodecyl sulphate/polyacrylamide gel electrophoresis by a fibrin overlay method. Secreted enzyme was in the active form. Further incubation of lysate or supernatant plasminogen activator with plasminogen did not produce any active enzyme species of Mr 36 000, unlike incubations of urokinase with plasminogen. Moreover, comparisons with other plasminogen activators of Mr 52 000 from transformed cell lines showed that the monocyte activator was unique in its resistance to monocyte minactivin, a specific inactivator of urokinase-type plasminogen activators, and in its sensitivity to human alpha 2-macroglobulin. It was therefore concluded that human monocyte plasminogen activator, although sharing an Mr of 52 000 in common with other such activators, is not identical to the high Mr form of urokinase or the plasminogen activators of transformed cells. On present evidence it is the least likely of these enzymes to be active extracellularly under normal physiological conditions.     

Macrophage plasminogen activator: modulation of enzyme production by anti-inflammatory steroids, mitotic inhibitors, and cyclic nucleotides.

Plasminogen activator production by cultured mouse peritoneal macrophages can be modulated in vitro by low concentrations of various pharmacologically active molecules. Glucocorticoid hormones and their synthetic derivatives, as well as cholera toxin, colchicine, and vinblastine markedly inhibit production of this enzyme without affecting other important macrophage functions. The effect of glucocorticoids is of particular interest, both because their relative in vivo anti-inflammatory potencies correlate exactly with their effect on plasminogen activator production in culture and because this effect occurs at near physiological concentrations. In view of the correlations established in other systems between plasminogen activator production and cell migration, we have also examined the age of the macrophages in thioglycollate-induced exudates. Confirming the results of Van Furth and Cohn (1968), we have found that the majority of these cells are young, having recently replicated and arrived in the peritoneal cavity. Using a fibrinagar overlay technique which allowed us to determine the production of plasminogen activator by individual cells. we have found that the majority of these cells produce the enzyme. The potential roles of plasminogen activator in monocyte migration and the relationship of this enzyme to the anti-inflammatory effect of gluccorticoids are correlated and emphasized.     

Inhibition of a plasminogen activator from oncogenic virus-transformed mouse cells by rabbit antibodies against the enzyme

Antisera were raised in rabbits against an electrophoretically pure 48 000 dalton plasminogen activator from mouse cells transformed by an oncogenic virus. The IgG fraction of the antisera inhibited 48 000 dalton mouse plasminogen activators from a variety of sources (neoplastic and nonneoplastic), a 29 00) dalton plasminogen activator from mouse urine and a 48 000 dalton plasminogen activator from rat urine. No inhibition was observed of a 75 000 dalton plasminogen activator extracted from mouse lung, of mouse plasmin or of plasminogen activators from human urine and from oncogenic-virus transformed chicken cells. The IgG antibodies were stronger and more specific inhibitors of the 48 000 dalton mouse plasminogen activator than any previously tested compounds.     

Activation of pro-urokinase and plasminogen on human sarcoma cells: a proteolytic system with surface-bound reactants

Human HT-1080 fibrosarcoma cells produce urokinase-type plasminogen activator (u-PA) and type 1 plasminogen activator inhibitor (PAI-1). We found that after incubation of monolayer cultures with purified native human plasminogen in serum-containing medium, bound plasmin activity could be eluted from the cells with tranexamic acid, an analogue of lysine. The bound plasmin was the result of plasminogen activation on the cell surface; plasmin activity was not taken up onto cells after deliberate addition of plasmin to the serum-containing medium. The cell surface plasmin formation was inhibited by an anticatalytic monoclonal antibody to u-PA, indicating that this enzyme was responsible for the activation. Preincubation of the cells with diisopropyl fluorophosphate-inhibited u-PA led to a decrease in surface-bound plasmin, indicating that a large part, if not all, of the cell surface plasminogen activation was catalyzed by surface-bound u-PA. In the absence of plasminogen, most of the cell surface u-PA was present in its single-chain proenzyme form, while addition of plasminogen led to formation of cell-bound two-chain u-PA. The latter reaction was catalyzed by cell-bound plasmin. Cell-bound u-PA was accessible to inhibition by endogenous PAI-1 and by added PAI-2, while the cell-bound plasmin was inaccessible to serum inhibitors, but accessible to added aprotinin and an anticatalytic monoclonal antibody. A model for cell surface plasminogen activation is proposed in which plasminogen binding to cells from serum medium is followed by plasminogen activation by trace amounts of bound active u-PA, to form bound plasmin, which in turn serves to produce more active u-PA from bound pro-u-PA. This exponential process is subject to regulation by endogenous PAI-1 and limited to the pericellular space.     

A cell population in nu/nu spleen can prevent generation of cytotoxic lymphocytes by normal spleen cells against self antigens of the nu/nu spleen.

Spleen cells from athymic nu/nu mice contain two kinds of physically separable active cells that can have very different effects on the generation of CL (cytotoxic lymphocytes) by normal LN cells in an in vitro response against allogeneic stimulator cells. They can provide an accessory cell required for the activation of CLP (cytotoxic lymphocyte precursor cells) which need not be H-2 identical to the CLP and will function normally even when H-2 identical to the stimulator cells. They can also provide a suppressor cell that prevents the activation of CLP that can recognize the H-2 of the nu/nu mouse. Thus, with A, B, and C to represent three H-2 differnt mouse strains, a culture containing CLP from strain A and nu/nu spleen cells from strain B or strain (A x B)F1 will produce CL against strain C or (A x C)F1 stimulator cells but not against strain B or strain (A x B)F1 stimulator cells unless the suppressor cell is first removed. It is proposed that the in vivo role of the suppressor cell in a normal mouse is to prevent the activation of CLP reactive against self.     

A cellular binding site for the Mr 55,000 form of the human plasminogen activator, urokinase

The secretion of plasminogen activators has been implicated in the controlled extracellular proteolysis that accompanies cell migration and tissue remodeling. We found that the human plasminogen activator urokinase (Uk) (Mr 55,000 form) binds rapidly, specifically, and with high affinity to fresh human blood monocytes and to cells of the monocyte line U937. Upon binding Mr 55,000 Uk was observed to confer high plasminogen activator activity to the cells. Binding of the enzyme did not require a functional catalytic site (located on the B chain of the protein) but did require the noncatalytic A chain of Mr 55,000 Uk, since Mr 33,000 Uk did not bind. These results demonstrate the presence of a membrane receptor for Uk on monocytes and show a hitherto unknown function for the A chain of Uk: binding of secreted enzyme to its receptor results in Uk acting as a membrane protease. This localizes plasminogen activation near the cell surface, an optimal site to facilitate cell migration.     

Mouse ovarian granulosa cells produce urokinase-type plasminogen activator, whereas the corresponding rat cells produce tissue-type plasminogen activator

It is well established that rat ovarian granulosa cells produce tissue plasminogen activator (tPA). The synthesis and secretion of the enzyme are induced by gonadotropins, and correlate well with the time of follicular rupture in vivo. We have found that in contrast, mouse granulosa cells produce a different form of plasminogen activator, the urokinase-type (uPA). As with tPA synthesis in the rat, uPA production by mouse granulosa cells is induced by gonadotropins, dibutyryl cAMP, and prostaglandin E2. However, dexamethasone, a drug which has no effect on tPA synthesis in rat cells inhibits uPA synthesis in the mouse. Results of these determinations made in cell culture were corroborated by examining follicular fluid, which is secreted in vivo predominantly by granulosa cells, from stimulated rat and mouse ovarian follicles. Rat follicular fluid contained only tPA, and mouse follicular fluid only uPA, indicating that in vivo, granulosa cells from the two species are secreting different enzymes. The difference in the type of plasminogen activator produced by the rat and mouse granulosa cells was confirmed at the messenger RNA level. After hormone stimulation, only tPA mRNA was present in rat cells, whereas only uPA mRNA was found in mouse cells. Furthermore, the regulation of uPA levels in mouse cells occurs via transient modulation of steady-state levels of mRNA, a pattern similar to that seen with tPA in rat cells.     

Influence of macrophage products on the release of plasminogen activator, collagenase, beta-glucuronidase and prostaglandin E2 by articular chondrocytes.

We describe the effects of products of mononuclear phagocytes on the secretory activity of chondrocytes. The primary confluent cultures of rabbit articular chondrocytes were exposed to standard medium alone or enriched with conditioned medium obtained from cultures of rabbit peritoneal macrophages, the mouse macrophage cell line P388D1 or human blood mononuclear cells. Four markers of release were assessed, the neutral proteinases plasminogen activator and collagenase, the acid hydrolase beta-glucuronidase and prostaglandin E2, and the kinetics of their changes were monitored. Chondrocytes that were cultured in standard medium secreted large amounts of plasminogen activator, some beta-glucuronidase, but no collagenase, and released only minor amounts of prostaglandin E2. The addition of conditioned medium from rabbit macrophages induced a rapid release of large quantities of prostaglandin E2 and an abundant secretion of collagenase, while abolishing or strongly decreasing plasminogen activator secretion. In addition, beta-glucuronidase secretion was markedly enhanced. The decrease in secretion of plasminogen activator appeared to reflect a diminished production, since no evidence was found for the generation of inhibitors or for an accelerated extracellular breakdown of the enzyme. Conditioned media of the mouse and human mononuclear cells influenced the secretory activities of rabbit articular chondrocytes in a similar way, suggesting that the factor (or factors) acting on chondrocytes is produced by a variety of macrophages, and that its action is not species-restricted. The time course and concentration-dependence of the effects observed indicate that the secretion of plasminogen activator and collagenase are influenced in a strictly reciprocal fashion by the macrophage products. The release of prostaglandin E2 paralleled that of collagenase.     

Interaction of cells from murine organs with liposomes of various composition

The distribution of liposomes prepared from total mouse liver lipids and containing (3H)-labelled platelet activation factor in mouse organs was studied. It was shown that the majority of intraperitoneally injected liposomes prepared from total mouse liver lipids were transported to mouse liver and spleen. The interaction of liposomes with spleen cells in vitro revealed that the affinity of liposomes prepared from total spleen macrophage or total spleen lymphocyte lipids for mouse spleen cells was much higher than that of liposomes prepared from a model lipid mixture. The liposome binding to isolated spleen macrophages or lymphocytes was much higher than the liposome uptake by these cells in the total population of mouse spleen cells.     

Phorbol ester activation of a proteolytic cascade capable of activating latent transforming growth factor-betaL a process initiated by the exocytosis of cathepsin B

12-O-Tetradecanoylphorbol-13-acetate (TPA) suppresses the proliferation of the human breast epithelial cell line MCF10A-Neo by initiating proteolytic processes that activate latent transforming growth factor (TGF)-beta in the serum used to supplement culture medium. Within 1 h of treatment, cultures accumulated an extracellular activity capable of cleaving a substrate for urokinase-type plasminogen activator (uPA) and tissue plasminogen activator (tPA). This activity was inhibited by plasminogen activator inhibitor-1 or antibodies to uPA but not tPA. Pro-uPA activation was preceded by dramatic changes in lysosome trafficking and the extracellular appearance of cathepsin B and beta-hexosaminidase but not cathepsins D or L. Co-treatment of cultures with the cathepsin B inhibitors CA-074 or Z-FA-FMK suppressed the cytostatic effects of TPA and activation of pro-uPA. In the absence of TPA, exogenously added cathepsin B activated pro-uPA and suppressed MCF10A-Neo proliferation. The cytostatic effects of both TPA and cathepsin B were suppressed in cells cultured in medium depleted of plasminogen/plasmin or supplemented with neutralizing TGF-beta antibody. Pretreatment with cycloheximide did not suppress the exocytosis of cathepsin B or the activation of pro-uPA. Hence, TPA activates signaling processes that trigger the exocytosis of a subpopulation of lysosomes/endosomes containing cathepsin B. Subsequently, extracellular cathepsin B initiates a proteolytic cascade involving uPA, plasminogen, and plasmin that activates serum-derived latent TGF-beta.