The human LT serum. X. The initial form released by T-enriched lymphocytes is 150,000 m.w., associated with small nonlytic components, and can dissociate into the smaller alpha, beta, and gamma m.w. classes

The present studies examine the various lymphotoxin (LT) forms released in vitro by phytohemagglutinin- (PHA) activated T-enriched (Te) human peripheral blood lymphocytes. It is clear that Te cells rapidly released (24 to 48 hr) these molecules in vitro. The 1st cell-lytic form detected in these supernatants is a 140-160,000 m.w. molecule(s) termed precursor alpha heavy (P alpha H). This form does not express alpha-LT antigenic determinants but is neutralized by antisera from animals injected with serum-free PHA-activated unseparated lymphocyte supernatants (anti-WS). The P alpha H is converted into alpha H, which expresses alpha determinants, by passage through molecular sieving columns or by treatment with low levels of Nonidet P-40 or urea. These treatments dissociate a small nontoxic 10-20,000 m.w. molecule(s), termed precursor factor (Pf), which masks the alpha-LT determinant on the P alpha H molecule. The dissociation of Pf is reversible, since alpha H from the molecular sieving columns will reassociate with the Pf. The alpha H LT class can further dissociate into the smaller alpha, beta, and gamma LT forms upon chromatography on a molecular sieving column, and a certain small percentage of the alpha H forms appear capable of associating to form the high m.w. complex (Cx) LT class. These findings suggest P alpha H may represent an intermediate that requires additional processing in order to proceed down 1 of 2 pathways: a) formation of complexes that are highly cell-lytic, or b) degradation by dissociation into the smaller weakly cell-lytic molecules identified as LT forms.     

The human LT system. II. Immunological relationships of LT molecules released by mitogen activated human lymphocytes in vitro.

Materials with LT activity present in supernatants from PHA stimulated human lymphocytes in vitro are very heterogeneous and can be separated into multiple molecular weight classes, termed complex, α, β, and γ. Several of these classes can be further resolved into subclasses by other physical and chemical methods. The immunologic relationships of these materials one to another were examined employing various rabbit anti-humn LT sera which will neutralize LT activity on L-929 cells in vitro. These studies reveal: (a) LT activities are due to a distinct group of substances which are immunologically related one to another and can exist in several molecular weight forms; (b) a high MW class of molecules, termed complex, appears to contain all currently known LT classes and subclasses; (c) LT classes and subclasses both have common (public) and discrete (private) antigenic specificities; (d) human LT classes and subclasses do not appear to share Ag determinants with materials with LT activity released by lectin stimulated lymphoid cells from rabbit, rat, hamster, guinea pig, or mouse; and (e) human LT molecules are not immunologically related to cell toxins released by glass adherent human peripheral blood monocytes or PMN cells. These data indicate human LT molecules form a “discrete system” of lymphocyte derived cell toxins, which can associate together into various related but different MW forms in the supernatant.     

The human LT system. V. A comparison of the relative lytic effectiveness of various MW human LT classes on 51Cr-labeled allogeneic target cells in vitro: enhanced lysis by LT complexes associated with Ig-like receptor(s).

The present studies examine the in vitro cell-lytic capacity of various molecular weight (MW) human lymphotoxin (LT) classes obtained from lectin-activated normal or immune lymphocytes on allogeneic target cells. The findings reveal that the high-MW complex class of LT is up to 100 times more effective than the smaller MW LT forms (α, β, and γ) in causing lysis of various allogeneic cell types including lymphoid cells in vitro. Moreover, the data suggest that lectin-stimulated alloimmune cells (MLC sensitized) release complex LT forms in association with a specific antigen-binding receptor(s), and that these complexes are from 3 to 10 times more effective on the sensitizing target cell than complexes obtained from lectin-stimulated nonimmune cells. Positive evidence that complex-induced lysis involved LT was indicated by the finding that lysis was completely neutralized by incubation with heterologous antisera directed against a refined human α₂-LT subclass (anti-α₂) and partially neutralized with anti-human Fab₂′ serum. These findings support the concept that LT molecules may represent a system of related cell-lytic molecules. While the smaller MW forms are only weakly lytic by themselves, they can be assembled into highly lytic complexes which may be focused or directed by an antigen-binding receptor(s).     

Generation and characterization of hamster monoclonal antibodies that neutralize murine tumor necrosis factors

mAb to murine TNF (MuTNF) were produced after immunization of Armenian hamsters with purified, Escherichia coli-derived rMuTNF-alpha. Antibody produced from clone TN3-19.12, was purified and was found to inhibit 100% of the lytic activity of either recombinant or natural MuTNF-alpha at an antibody input of 25 ng/U. TN3-19.12 also inhibited all the lytic activity in culture supernatants from a variety of T cell sources, including activated T cell clones and T cell hybridomas (all of which expressed high levels of TNF-alpha and TNF-beta (lymphotoxin, LT) mRNA). Western blot analysis was used to document the physical form(s) of MuTNF recognized by TN3-19.12. Recombinant and macrophage-derived TNF displayed identical patterns of a single band with Mr 17 kDa. In contrast, T cell culture supernatants exhibited patterns consisting of two bands with Mr 17 and 24.7 kDa. The higher m.w. form was glycosylated based on its sensitivity to n-glycanase and displayed a m.w. consistent with that of TNF-beta (LT). These data suggest that TN3-19.12 recognizes both MuTNF-alpha and MuTNF-beta (LT). Monoclonal TN3-19.12 and polyvalent rabbit anti-rTNF were used to establish a MuTNF-specific ELISA capable of detecting picogram quantities of recombinant or natural TNF. This assay was used to detect TNF in the sera of mice challenged with a lethal dose of LPS. Peak TNF serum levels of 11 ng/ml were observed in these animals 90 min after i.p. LPS administration and then rapidly declined to near base line levels by 3 h. These values were confirmed by quantitating levels of TNF functional activity in the same samples. TN3-19.12 injected into mice subsequently treated with LPS prevented the detection of TNF in the circulation by either assay and protected mice from the lethal effects of endotoxin shock. Thus, TN3-19.12 effectively neutralizes endogenously produced TNF in vivo.     

Cytotoxic activity of lymphocytes. VII. cellular origin of alpha-lymphotoxin.

To detect the cellular origins of alpha-lymphotoxin (alpha-LT), we cultured various subpopulations of human blood lymphocytes separated by erythrocyte-rosetting techniques with various mitogens. T cell-enriched subpopulations responded to PHA by increased 3H-thymidine uptake into DNA and large amounts of alpha-LT production. SPL and Con A-Sepharose stimulated DNA synthesis in T cell-enriched cultures if the macrophage content was greater than 1.5%; however, alpha-LT production was not induced by these two mitogens even when reconstituted with 10% macrophages. B and/or null cell-enriched populations severely depleted of T cells (less than 0.7% did not respond to PHA, SPL, or Con A-Sepharose. However, reconstitution to 5 or more percent in E-RFC allowed all three mitogens to stimulate DNA synthesis and alpha-LT production. The LT made by all cell populations 5 and 7 days after stimulation were equally neutralized by a heterologous antiserum to alpha-LT. These results show that human T and B and/or null cells, when appropriately stimulated, can produce alpha-LT.     

A physicochemical and immunologic comparison of the cell growth inhibitory activity of human lymphotoxins and interferons in vitro.

The physicochemical, immunologic, and biologic relationships between humam lymphotoxins (LT) and interferons (IF) present in supernatant fluids from lectin-stimulated peripheral blood lymphocytes (PBL) and a continuous B-lymphoblastoid cell line (PGLC-33h) were analyzed. LT activity obtained from lectin-activated PBL could not be resolved from IF activity by gel filtration chromatography. LT activity eluted in multiple peaks of activity at 70 to 90,000, and 40 to 50,000 m.w., characteristic of alpha and beta LT, respectively. IF activity in these supernatant fluids eluted as a broad band between 35 and 80,000 m.w., also suggestive of molecular heterogeneity. In contrast, this m.w. heterogeneity was not observed in LT and IF activities obtained from the PGLC-33h cell line. LT and IF eluted as separate peaks of activity at 90,000 and 25,000 m.w., respectively. In addition, acid and heat lability of PGLC-33h IF suggested similarity to type II IF. Immunologic studies, with a rabbit anti-alpha class serum that neutralized LT activity from both PBL and PGLC-33h, did not affect IF activity from either of these sources. Supernatant fluids from PGLC-33h cultures were also capable of inhibiting the proliferation of HeLa cells in vitro. The growth inhibitory activity was attributed to LT- and IF-like molecules. This evidence suggests that although cytotoxic and anti-viral activities were due to separate molecules, LT and IF have overlapping biologic activities in their ability to inhibit the proliferation of cells in vitro.     

Mechanism of human lymphotoxin and tumor necrosis factor induced destruction of cells in vitro: phospholipase activation and deacylation of specific-membrane phospholipids

The role of phospholipase (PLase) activation and lipid metabolism in lymphotoxin (LT)- and tumor necrosis factor (TNF)-mediated destruction of murine L929 cells was examined. At the levels of LT and TNF employed, cell destruction began at 4-6 h and was 99% complete by 30 h. Cell membrane phospholipids (PL), labelled in situ at the C2 position with 14C arachidonic acid, were analyzed by two-dimensional thin-layer chromatography and quantitated over a 30 h time course after LT or TNF treatment. The ratio of radiolabel incorporation relative to the actual amount of each PL present was determined by inorganic phosphate analysis. Radiolabelled arachidonic acid, eicosanoids, and neutral lipids were released into the medium prior to the onset of cell death (4-6 h) and continued to accumulate linearly throughout the destructive reaction. There was a quantitative relationship between the appearance of radiolabelled metabolites in the media and the loss of radiolabelled cellular PL. Cellular phosphatidylethanolamine was the primary PL deacylated by PLase action, showing a 75% reduction in radiolabel. The PLase inhibitors--quinacrine, hydrocortisone, dexamethasone, and indomethacin--were potent inhibitors of LT- and TNF-mediated cell destruction, suggesting that selective deacylation of specific membrane PL by PLase activation is an important step in the events that lead to LT- and TNF-mediated cellular destruction in vitro.     

The human LT system. III. Characterization of a high molecular weight LT class (complex) composed of the various smaller MW LT classes and subclasses in association with Ig-like molecules.

Cytotoxic activity (lymphotoxin (LT)) present in supernatants from lectin stimulated human lymphocytes in vitro is composed of a heterogeneous system of biological macromolecules which can be separated into multiple classes and subclasses on the basis of their molecular weight and charge. These studies further characterize a large molecular weight human LT class, termed complex (MW >200,000 d), which elutes in the void volume off Sephadex G-150 or Ultrogel AcA 44. Immunological studies on the complex, employing various rabbit anti-LT class and subclass antisera, revealed this material is a macromolecular assemblage of the smaller MW α, β, γ LT classes and subclasses. Furthermore, the reactivity of this material with anti-human Fab′₂ (IgG) indicates these smaller molecular weight LT components can associate with immunoglobulin or Ig-like molecules. The materials present in the LT complex class appear to be noncovalently associated, since conditions of high ionic strength dissociate certain small MW LT components, while low ionic strength buffers may cause these components to reaggregate with the complex. When subjected to velocity sedimentation on sucrose gradients or gel filtration on Ultrogel AcA 22, LT complex activity elutes as several discrete peaks of activity in the 200,000 to 1,000,000 MW range. These findings suggest the concept that LT molecules can form discrete and specific macromolecular structures which contain the smaller MW LT classes. Moreover, these structures can also associate with immunoglobulin-like molecules to form secondary LT-Ig complexes. This may have important biological significance in explaining how nonspecific cell toxins could play a role in specific or nonspecific cell lytic reactions in vitro.     

Cytotoxic lymphokines produced by cloned human cytotoxic T lymphocytes. II. A novel CTL-produced cytotoxin that is antigenically distinct from tumor necrosis factor and alpha-lymphotoxin

We have cloned lines of IL 2-dependent human T cells derived from alloantigen, soluble antigen (tetanus toxoid), mitogen, or IL 2-stimulated peripheral blood lymphocytes and characterized their surface marker expression and cytolytic activity. The surface phenotype and cytolytic function was compared with the ability of these T cell clones to release cytotoxic lymphokines in response to mitogenic lectins. The cytotoxins released by these CTL clones were detected on the murine L929 target cells in a 16-hr assay. All of the T cell clones, whether stimulated by HLA alloantigens, tetanus toxoid, or mitogens, exhibited killer cell activity and the capacity to secrete a soluble cytotoxin(s). Specific polyclonal antisera to recombinant human tumor necrosis factor (rTNF) and human alpha-lymphotoxin (alpha LT) were unable to neutralize the cytotoxic activity released by most of these CTL clones. These results indicate that human CTL produce a novel antigenic form(s) of cytotoxin that we have termed CTL-toxin. Supernatants from several CTL clones yielded a cytotoxic activity that was partially neutralized (10 to 40%) by saturating levels of anti-TNF (but not anti-alpha LT) indicating that human CTL may be capable of producing a TNF-like molecule. Only two out of 60 CTL clones studied thus far produced a cytotoxic activity that was partially neutralized by anti-alpha LT (20 to 40%). Collectively, these results suggest that although both the CD4 and the CD8 subpopulations of human cytotoxic T cells may be capable of releasing several types of cytotoxins in response to mitogenic signals, the predominant cytotoxin is distinct from alpha LT and TNF.     

Characterization of the receptor for tumor necrosis factor (TNF) and lymphotoxin (LT) on human T lymphocytes. TNF and LT differ in their receptor binding properties and the induction of MHC class I proteins on a human CD4+ T cell hybridoma

TNF-alpha and lymphotoxin (LT or TNF-beta) are structurally related cytokines that share several proinflammatory and immunomodulatory activities. The shared biologic activities of TNF and LT have been attributed to their binding to a common cell surface receptor(s). We observed that rTNF enhanced the expression of MHC class I proteins on the human T cell hybridoma, II-23.D7, however LT was largely unable to regulate MHC expression. To determine the molecular basis of this disparity between LT and TNF the receptor binding characteristics of rTNF and rLT were investigated by direct and competitive radioligand assays on the II-23.D7 T hybridoma, and for comparison, anti-CD3 activated human T lymphocytes. Specific 125I-rTNF binding to the II-23.D7 line revealed a single class of sites with a Kd = 175 pM and 3000 sites/cell; anti-CD3 activated T cells exhibited specific TNF binding with similar properties. The relationship of receptor occupancy to the induction of MHC class I Ag yielded a hyperbolic curve indicating a complex relationship between rTNF binding and biologic response. LT appeared to function like a partial agonist in that rLT was 10- to 20-fold less effective than rTNF in competitively inhibiting 125I-rTNF binding on the II-23.D7 line. Scatchard type analysis revealed a single class of low affinity binding sites for 125I-rLT. No differences in the competitive binding activity of rTNF and rLT were observed on the anti-CD3-activated T cells. Receptors for rTNF and rLT were immunoprecipitated from the II-23.D7 and activated T cells with anticytokine antibodies after cross-linking of radioiodinated rTNF or rLT to intact cells by using chemical cross-linking reagents. Analysis of the cross-linked adducts by SDS-PAGE and autoradiography indicated a major adduct of 92 kDa for rTNF and 104 kDa for rLT. Enzymatic digestion with neuraminidase or V8 protease revealed a unique structure to these adducts consistent with the cross-linking of a single chain of cytokine to a cell surface glycoprotein. rTNF inhibited the formation of the 104-kDa adduct formed with 125I-rLT on the II-23.D7 line, indicating these two cytokines bind to the same receptor of approximately 80 kDa. These results suggest that the disparate activities of LT and TNF to induce MHC class I proteins on the II-23.D7 cells are, in part, associated with a modified state of a common receptor.     

The human LT system. VII. Release of soluble forms and delivery to target L-929 cells by lectin-preactivated human lymphocytes in the absence of protein synthesis and secretory processes.

We have investigated the effects of inhibitors of cellular protein synthesis (emetine, cycloheximide) and secretion (colchicine, cytochalasin B) on the capacity of primary or secondary lectin-activated human lymphocytes to release LT molecules or to cause lectin-induced destruction (LICC) of murine L-929 cells in vitro. Our findings reveal: (a) agents which inhibit protein synthesis or secretion block the release of LT activity into the supernatant and LICC when primary lectin-stimulated human adenoid lymphocytes are employed as effector cells; (b) these same agents are ineffective at blocking LT release or LICC when 3- or 5-day lectin-prestimulated lymphocytes are employed; and (c) anti-human α-LT serum blocks LICC of L-929 cells mediated by primary or secondary lectin-activated human lymphocytes. The difference in participation of effector cellular processes in LICC between primary and secondary lectin-stimulated cells correlates with the findings that preactivated lymphoid cells possess high levels of preformed intracellular, as well as membrane associated, LT molecules, and that release of these materials into the supernatant or delivery to the target cell can occur independently of active protein biosynthesis or classical secretory systems.     

Inhibition of human lymphocyte-mediated mitogen-induced cytotoxicity of murine L-929 cells by heterologous anti-human lymphotoxin antisera in vitro.

Heterologous anti-human lymphotoxin (LT) antisera have been employed to investigate the role of LT in mitogen-(Con-A, PHA) induced destruction of murine L-929 cells by human lymphocytes in vitro. These various antisera will effectively neutralize human LT molecules associated with the stable (70 to 90,000 dalton) alpha-LT class of cytotoxin (anti-alpha-LT), the more unstable (35 to 50,000 dalton) beta-LT class of cytotoxins (anti-beta-LT), and antisera which will neutralize all classes of these cytotoxins in vitro, anti-whole supernatant (anti-W.S.). These anti-LT sera will greatly inhibit lysis of L-929 cells by using mitogen-activated human effector lymphocytes in vitro. This blocking was shown to be mediated by whole serum, purified IgG, or IgG-Fab fragments, which had been extensively absorbed with bovine serum, human serum, mitogens, and normal human lymphocytes. Inhibition of lysis was not apparently due to interference with either lymphocyte-target cell contact or lymphocyte activation step(s). The blocking effects of these sera were also shown to occur during the lymphocyte-independent phase of the lytic reaction. These data support the concept that the lymphocyte deposits an LT-like effector molecule on the target-L cell surface during the lymphocyte-dependent phase, which mediates cell lysis at a later time during the lymphocyte-independent phase.     

Inhibition of human NK-induced cell lysis and soluble cell-lytic molecules with anti-human LT antisera and various saccharides

The present study examines and compares the cytolysis of K-562 and MOLT-4 cells mediated by human natural killer (NK) cells from fresh peripheral blood and lymphotoxins (LT) derived from human lymphoid cell populations after lectin stimulation in vitro. Lymphotoxins were obtained from 5-hr concanavalin A (Con A)-restimulated human peripheral blood lymphocytes (PBL) which were precultured for 5 days in medium and fetal calf serum or with allogeneic human B-lymphoid cell lines. Two classes of probes were employed in both direct (cell) and indirect (supernatant) induced target-cell lysis: (a) various saccharides and (b) antibodies reactive with human LT forms. Two sugars, N-acetylglucosamine and α-methylmannoside, were able to inhibit direct cell lysis of both MOLT-4 and K-562 target cells. However, saccharide inhibition was distinct for each type of target even when effector cells were obtained from the same donor. These same saccharides were also able to inhibit 20–30% of the total LT activity in a supernatant for L-929 cells and 50–90% of the lytic activity on MOLT-4 cells. Anti-human F(ab′)₂ (IgG) and rabbit anti-α₂ LT sera blocked direct cell lysis of MOLT-4 and K-562 targets in 50% of the experiments. The anti-α₂ LT serum only recognizes a portion of the LT forms in these supernatants. These results reveal that, while both direct and indirect cell lysis are complex phenomena, they may both occur in some cases by a common mechanism(s).     

Identification of membrane-associated lymphotoxin (LT) on mitogen-activated human lymphocytes using heterologous anti-LT antisera in vitro.

Surface-associated lymphotoxin (LT) molecules have been identified on mitogen-activated human lymphocytes employing heterologous anti-α-LT serum in vitro. These membrane-associated LT molecules are present on PHA- or Con A-activated lymphocytes but do not appear to be expressed on unstimulated cells. Furthermore, these molecules were detected primarily on activated T lymphocytes, with little detectable on activated B- or null-cell populations. The removal of surface LT-bearing lymphocytes, using anti-α-LT serum + C′, does not dramatically affect the capacity of the remaining cells to release LT after mitogen restimulation. In addition, the presence of toxic molecules on the surface of activated lymphocytes suggests that these materials may be expressed in an inactive, noncytotoxic form.     

Lymphotoxin and an associated 33-kDa glycoprotein are expressed on the surface of an activated human T cell hybridoma.

A human T cell hybridoma, II-23.D7, was induced with phorbol ester to express a surface form of lymphotoxin (LT, TNF-beta) and an associated 33-kDa glycoprotein. The LT epitopes were detected by surface immunofluorescence staining and by immunoprecipitation from radioiodinated or biosynthetically labeled cells with the use of anti-rLT polyclonal and monoclonal antibodies. The epitopes detected by the antibody were related to LT because adsorption of the anti-rLT with PMA-activated II-23.D7 cells resulted in the removal of the neutralizing titer of the anti-rLT antiserum. Immunoprecipitation of surface radioiodinated II-23.D7 cells revealed two bands of 25 kDa and 33 kDa that were specifically precipitated with anti-rLT, but not anti-rTNF antibodies. Enzymatic digestion with glycanases showed both proteins to have N-linked carbohydrate, with O-linked sugar limited to the 25-kDa protein. To determine the biochemical relationship between these proteins, the two LT-like forms were purified from detergent-solubilized II-23.D7 cells by immunoaffinity chromatography. Peptide mapping using CNBr cleavage showed the 25-kDa surface form to be identical to rLT, whereas the 33-kDa protein was different. Biosynthetic labeling studies showed that p33 contained both methionine and cysteine, whereas the p25 contained only methionine. Thus, the surface LT form lacks a leader peptide indicating an anchoring mechanism distinct from that described for membrane TNF. The nature of the attachment of this LT form to the membrane surface is not clear, however, neither TNF receptor binding nor lipid linkages appear to be involved. The accessory protein, p33, may anchor LT to the surface. These findings identify a new characteristic of LT and point toward an additional pathway by which T lymphocytes may mediate cytolytic activity and regulate inflammatory processes.     

Simian virus 40 small tumor antigen activates AKT and telomerase and induces anchorage-independent growth of human epithelial cells

Human keratinocytes immortalized by full-length or early-region simian virus 40 (SV40) DNA grow in agarose and form tumors in nude mice, in contrast to keratinocytes immortalized by the E6/E7 genes of human papillomaviruses. To determine the molecular basis for this biological difference in growth, we have used the individual SV40 oncogenes (large T antigen [LT] and small t antigen [st]) and human papillomavirus oncogenes (E6/E7) to study the progression of human epithelial cells from the nonimmortal to the immortal state as well as from the immortal to the anchorage-independent state. Transfection of primary human foreskin keratinocytes with LT did not immortalize cells but did extend the in vitro life span and produced cells that were resistant to calcium- and serum-induced terminal differentiation. Cells transfected with st alone did not passage beyond vector-transfected keratinocytes. The simultaneous expression of LT- and st-immortalized keratinocytes occurred without evidence of crisis and, as anticipated, these immortal cells were anchorage- independent for growth. Interestingly, we found that keratinocytes expressing both LT and st, but not keratinocytes with LT alone, exhibited increased phosphorylation of the protein kinase AKT. In addition, AKT activation was paralleled by an increase in telomerase activity. Addition of st to anchorage-dependent keratinocytes, expressing either LT (nonimmortal) or E6/E7 (immortal), converted the cells to anchorage independence, with similar accompanying increases in AKT phosphorylation and telomerase activity. However, it was not possible to induce keratinocyte growth in agarose with activated AKT and/or overexpressed hTERT, indicating that these newly defined st-induced activities are not sufficient for progression to the anchorage-independent state.     

Functional diversity of heat-labile toxins (LT) produced by enterotoxigenic Escherichia coli: differential enzymatic and immunological activities of LT1 (hLT) AND LT4 (pLT)

Heat-labile toxins (LTs) have ADP-ribosylation activity and induce the secretory diarrhea caused by enterotoxigenic Escherichia coli (ETEC) strains in different mammalian hosts. LTs also act as adjuvants following delivery via mucosal, parenteral, or transcutaneous routes. Previously we have shown that LT produced by human-derived ETEC strains encompass a group of 16 polymorphic variants, including the reference toxin (LT1 or hLT) produced by the H10407 strain and one variant that is found mainly among bacterial strains isolated from pigs (LT4 or pLT). Herein, we show that LT4 (with six polymorphic sites in the A (K4R, K213E, and N238D) and B (S4T, A46E, and E102K) subunits) displays differential in vitro toxicity and in vivo adjuvant activities compared with LT1. One in vitro generated LT mutant (LTK4R), in which the lysine at position 4 of the A subunit was replaced by arginine, showed most of the LT4 features with an ～10-fold reduction of the cytotonic effects, ADP-ribosylation activity, and accumulation of intracellular cAMP in Y1 cells. Molecular dynamic studies of the A subunit showed that the K4R replacement reduces the N-terminal region flexibility and decreases the catalytic site crevice. Noticeably, LT4 showed a stronger Th1-biased adjuvant activity with regard to LT1, particularly concerning activation of cytotoxic CD8(+) T lymphocytes when delivered via the intranasal route. Our results further emphasize the relevance of LT polymorphism among human-derived ETEC strains that may impact both the pathogenicity of the bacterial strain and the use of these toxins as potential vaccine adjuvants.     

Regulatory factors produced by lymphocytes. I. The occurrence of multiple alpha-lymphotoxins associated with ribonuclease activity.

Supernatant fluids of mitogen-activated human tonsil lymphocytes contain large amounts of a factor toxic to mouse L cells. This substance, with a m.w. of 80,000 +/- 5,000 daltons, is called alpha-lymphotoxin (alpha-LT), to differentiate it from another toxin elaborated by mitogen activated human blood lymphocytes, called beta-lymphotoxin (beta-LT), which differs from alpha-LT in size (45,000 +/- 5,000 daltons), antigenicity, and stability. Further purification of alpha-LT by sequential phosphocellulose and DEAE-cellulose chromatography and polyacrylamide gel electrophoresis (PAGE) identifies a series of cytotoxins differing in ion exchange characteristics and electrophoretic mobilities. The three PAGE fractions (PAGE Ia, Ib and II), recovered in 2, 4.6, and 21% yield from the starting serum-free culture supernatant, represent purifications of 24-, 24- and 1851-fold, respectively. Each cytotoxic fraction has a ribonuclease activity. Comparison of RNase and mouse L cell cytotoxic activities of the three alpha-LT fractions shows that both activities for all three fractions have a similar temperature stability pattern and that both are similarly inhibited by DNA, single strand forms better than double strands, by glycerol in 5 to 20% concentration, and by protein denaturing reagents. These observations suggest, but do not prove, that mouse L cell toxicity and RNase activity are mediated by the same substance, which appears to occur in multiple or isozymic forms.     

Resistance to the cytolytic action of lymphotoxin and tumor necrosis factor coincides with the presence of gap junctions uniting target cells

The resistance of target cells to the cytolytic action of lymphotoxin (LT) and recombinant tumor necrosis factor (rTNF) has been investigated by using clonally derived cell lines with defined gap junction-mediated, intercellular communication properties. Gap junction-competent Chinese hamster ovary cells are normally insensitive to the action of LT/TNF. However, treatment with 12-o-tetradecanoylphorbol-13-acetate, which promotes the loss of gap junctions, or culturing at low cell density to reduce intercellular contacts, significantly increased their sensitivity to LT/TNF. The LT/TNF-sensitive murine CL-1D and L929 cell lines, which in normal culture conditions are unable to form gap junctions, were not changed in their susceptibility to LT/TNF after treatment with phorbol ester or low culture density. However, the formation of gap junctions by CL-1D can be promoted by treatment with 8-bromo-cyclic adenosine monophosphate (1 mM), and this treatment completely suppressed the ability of LT and rTNF to kill CL-1D. Additionally, the LA25-normal rat kidney cell line, which is infected with a temperature-sensitive mutant of Rous sarcoma virus (LA25), is gap junction-competent and resistant to the effects of LT at the restrictive temperature (39 degrees C). However, when shifted to the permissive temperature (33 degrees C), LA25-normal rat kidney cells express the pp60v-src viral gene product, lose their ability to form gap junctions, and become sensitive to the lytic activity of LT. The results demonstrate that the expression of the retroviral pp60v-src, a tyrosine protein kinase, is sufficient to render cells susceptible to the lytic effects of LT and rTNF. Collectively, these experiments demonstrate a strong correlation between the resistance of target cells to the action of LT/TNF and their ability to cooperate metabolically through gap junctions. The results do not completely exclude the possibility that other mechanisms, such as LT receptor modulation, are also occurring under these experimental conditions. These data also suggest that a possible physiologic function of the stable cytotoxic lymphokines is to induce cytolysis/cytostasis of cells that have lost gap junctional contact, such as those in the process of mitosis or metastasis that have separated from the main tissue mass.