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.     

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).     

The human LT system. IV. Studies on the large MW LT complex class: association of these molecules with specific antigen binding receptor(s) in vitro.

The present studies demonstrate that a portion of lymphotoxin (LT) cell-lytic activity present in supernatants from: 1) lectin (Con A, PHA) stimulated nonimmune; or 2) antigen (soluble or cellular) stimulated immune human lymphocytes in vitro, is associated with immunoglobulin (Ig) or “Ig-like” receptor molecule(s). This concept was supported by three findings: 1) LT activity in these supernatants was partially inhibited by heterologous anti-human (IgG) Fab′₂ antisera; 2) LT activity present in soluble antigen stimulated immune human lymphocyte supernatants could specifically bind to and be eluted from Sepharose 4B columns to which the specific stimulating antigen was covalently attached; and 3) LT activity present in primary one-way mixed lymphocyte culture (MLC) supernatants could be removed by absorption on the specific stimulator cells. The amount of total LT activity found to be associated with “Ig” in these supernatants was variable, but ranged from 5 to 20% in lectin stimulated cell supernatants to 20 to 50% in antigen or MLC stimulated supernatants. Physical-chemical studies on the molecular weight class of LT molecules having reactivity with anti-Fab′₂ sera, as well as antigen binding capacity, revealed these properties reside in the large (>200,000) MW LT class, termed complex. The nature and biological significance of these “antigen specific” LT complexes, as they relate to mechanisms of cytotoxicity in vitro, will be discussed.     

Identification of human lymphocyte-derived lymphotoxins with binding and cell-lytic activity on NK-sensitive cell lines in vitro

Supernatants obtained from lectin-restimulated, preactivated, human peripheral blood lymphocytes rapidly released (5–24 hr) high levels of lymphotoxin (LT) activity in vitro. Peripheral blood lymphocytes were preactivated by coculturing with either fetal calf serum or with allogeneic continuous B-cell lines (LCCL) which were treated with mitomycin C. These Supernatants contained a population of L-929 cell-lytic LT forms which also selectively bind to the NK-sensitive K-562 cell. However, lytic LT forms for L-929 cells from cPBL and LCCL cultures did not bind to the NK-sensitive MOLT-4 or NK-resistant Raji cells. Additional studies reveal these supernatants contain a second set of LT forms which have cell-binding and cell-lytic activity detectable on MOLT-4 and K-562 cells in a 12 to 18 hr ⁵¹Cr-release assay. Cell-lytic form(s) for the MOLT-4 and K-562 cells were not stable for more than a week at ?20°C. These findings indicate that materials with LT activity are heterogeneous with respect to their capacity to recognize common and discrete cell-surface components on different types of target cells in vitro.     

Stabilization and functional studies of high-molecular-weight murine lymphotoxins

High levels of lymphotoxin-like activity (LT) were found in supernatants from secondarily stimulated immune mouse splenocytes activated with concanavalin A (Con A) in vitro. Splenocytes obtained from C57Bl/6 mice immune to the P815 mastocytoma were restimulated in vitro with mitomycin C-treated P815 cells, and then stimulated with Con A. High levels of unstable LT activity are rapidly (2–4 hr) released by these lectin-stimulated splenocytes. The introduction of a crosslinking agent, glutaraldehyde, was found to stabilize this LT activity and allowed us to perform more defined biochemical studies and to examine the functional activities of the LT classes. The lytic activity in these supernatants resided in the high-molecular-weight classes, termed Complex (Cx > 200,000 daltons) and alpha-heavy (α_H 130,000–160,000 daltons). It was found that the Cx and α_H LT classes from the secondarily stimulated immune splenocytes cause lysis of allogeneic target cells, P815 and EL-4, in a 16-hr ⁷⁵Semethionine release assay, and in some cases, this lysis was specific for the sensitizing target cell.     

The human LT system. I. Physical-chemical heterogeneity of LT molecules released by mitogen activated human lymphocytes in vitro.

Molecules with LT activity which can be identified in supernatants from PHA stimulated human lymphocytes by lysis of murine L-929 cell in vitro are heterogeneous. They can be separated by MW on sephadex or ultrogel columns into four separate classes: (a) complex (>200,000 daltons); (b) α (70–90,000 d); (c) β (25–50,000 d); and (d) γ (10–20,000 d). The amount of activity in a supernatant due to each class varies but is approximately: Cx—5 to 20%, α—40 to 60%, β—20 to 40%, and γ—0 to 10%. These classes differ one from another in their stability and kinetics of appearance in culture. Furthermore, they may aggregate together with the complex class under conditions of low ionic strength. Each class, except γ, can be further separated into subclasses by ion exchange chromatography and polyacrylamide gel electrophoresis. Alpha class can be separated on DEAE into the three subclasses, termed, α₁ (rf 0.25), α₂ (rf 0.37), and α₃ (rf 0.50). Alpha₂ subclasses can be further separated on phosphocellulose at pH 6.6 into α_2a (rf 0.37) and α_2b (rf 0.30). However, α₂ contains additional subclasses, which were resolved on PC columns at pH 5.5. Beta class activity can be resolved by DEAE and PAGE into two subclasses, termed β₁ (rf 0.28) and β₂ (rf 0.49). Gamma class activity was not studied, because of its instability. The complex class of LT activity is a macromolecular aggregate greater than 200,000 daltons which appears to contain smaller MW LT class(es). This study demonstrates that materials with LT activity in supernatants from PHA activated human lymphocytes in vitro are very heterogeneous.     

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 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. 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.     

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.     

The human LT system. XII. Purification and functional studies of LT and "TNF-like" LT forms from a continuous human T cell line

A clone of the continuous human T cell line HUT-102, termed YM 1.2, can spontaneously release alpha-LT in vitro. However, when stimulated with phorbol myristic acetate, these cells release other LT forms. These LT forms were purified to homogeneity by DEAE chromatography, column isoelectric focusing, and polyacrylamide gel electrophoresis. One LT form, termed LT-2, is a 79,000 m.w. component in aqueous solution and composed of 21,000 m.w. subunits. This form is immunologically related to macrophage-derived TNF and has a lytic capacity in vitro on K-562, Molt-4F, and Raji cells similar to that described for cytotoxins derived from NK effector cells, termed NK-CF. A second LT form, termed LT-3, is a single 69,000 m.w. peptide which could not be reduced into the smaller subunits. This form expresses antigens in common with both alpha-LT and TNF, because both anti-LT and anti-TNF were required to completely neutralize cell lytic activity in vitro. Functional testing revealed that the LT-3 form is lytic on all continuous cells tested in vitro, including NK-resistant target cells. The LT-3 component appears similar by immunologic, biochemical, and functional criteria to the LT form derived from primary human cytolytic T cells in vitro. At the levels tested, none of these LT-TNF forms had measurable effects on primary fibroblasts in vitro.     

Higher cytolytic efficiency of an IgG2 alpha than of an IgG1 monoclonal antibody reacting with the same (or spatially close) determinant on a human high-molecular-weight melanoma-associated antigen

Serological and immunochemical assays showed that the monoclonal antibody (MoAb) 225.28S, an IgG_2α, and the MoAb 653.40S, an IgG₁, react with the same (or spatially close) antigenic determinant expressed on a set of molecules carrying a high-molecular-weight human melanoma-associated antigen. Neither monoclonal antibody mediates complement-dependent lysis of cultured melanoma cells, but both of them specifically mediate lysis of target cells in an antiglobulin cytotoxic assay and in an antibody-dependent cell-mediated cytotoxicity (ADCC) assay. In the latter two assays the IgG_2α displays a higher lytic activity than the IgG₁. The differential lytic activity of the IgG_2α and IgG₁ monoclonal antibodies was detected also when the sensitivity of the ADCC assay was increased either by boosting the cytolytic activity of the effector cells or by enhancing the susceptibility to lysis of target cells.     

An Adenosinetriphosphate-Activated Hemolytic System : III. Effect of rabbit hemolytic factor on the membrane permeability of human red cells

Lysis of human red cells in vitro by an enzyme obtained from rabbit red cell hemolysates and the inhibition of this lytic activity by human stroma have been shown to require Mg⁺⁺ and ATP, and ATP utilization has been demonstrated in both reactions. We find that sodium or potassium ions are also required for the lytic phenomenon and that they enhance the inhibition. The rate of hemolysis is not affected by the internal concentrations of these ions but depends only on the external concentration. The rate of influx and efflux of Na²²Cl and K⁴²Cl in surviving red cells is greatly enhanced both during and after treatment with rabbit hemolytic factor whereas the entry of C²⁴-sucrose, a small foreign molecule, is mediated only in the presence of hemolytic factor. Glycolysis neither protects against lysis nor enhances the activity of this system, and cardiac glycosides which are known inhibitors of active transport of ions also have no effect. It appears that lysis in this system is not brought about by increased active transport of ions into the cell but that the rabbit factor degrades or combines with some membrane component, altering permeability and resulting in increased diffusion, first of sodium and potassium ions and other small molecules, and finally of large molecules (hemoglobin) out of the cell.     

Macrophage--T cell interactions. I. The uptake by T cells of Fc receptors released from macrophages.

Using a rosette assay for the detection of cells carrying Fc receptors (Fc+) we have been able to show that in nylon wool (NWC), separated spleen cells from different strains of mice 12 to 18% are Fc+.Within 4 hr of culture in vitro at 37 °C, 75 to 85% of the Fc+ cells lose their Fc receptors and remain Fc receptor negative even after culture for 24 hr. However the addition of 5 to 10% syngeneic (but not allogeneic) peritoneal macrophages in the NWC, resulted in the preservation of the Fc receptors on 75 to 85% of the Fc+ cells originally present.Brief exposure of NWC which have been cultured in vitro for 4 hr (lost their Fc receptors) to supernates from 3 hr cultures of peritoneal macrophages reconstituted the fc+ cells by 75 to 85%. Only the supernates from syngeneic, but not allogeneic macrophages are active. Evidence is presented which indicates that these supernates contain Fc receptor molecules of small molecular weight. These molecules can be removed by antisera directed against the I region of the major histocompatibility complex.     

In vitro lymphocyte cytotoxicity. I. Evidence of multiple cytotoxic molecules secreted by mitogen activated human lymphoid cells in vitro.

Multiple families of cytotoxic molecules [Lymphotoxin (LT)] have been identified in phytohemagglutinin (PHA-P) activated human lymphocyte supernatants and lymphocyte homogenates, using gel filtration chromatography on Sephadex G-150. These macromolecules have molecular weights of 80–90,000, 50,000, and 10–15,000 daltons and have been termed LT₂, LT₂ and LT₃, respectively. They are secreted by cells from a variety of lympboid tissues, i.e., tonsil, adenoid, and peripheral blood. The kinetics of appearance of the cytotoxins indicate that all three are present within 16 hr after lymphocyte activation. However, while LT₁ and LT₂ persist in these cultures through day 5, LT₃ is not detectable after day 3. These molecules can also be detected when either PHA or concanavalin A are employed as the stimulating agent. Moreover, the relative amounts of LT₁, LT₂ and LT₃ activity in a given supernatant vary dramatically from culture to culture. Extracellular levels of LT accumulate and peak by 4 to 5 days in culture, however, intracellular levels of LT reach a maximum on day 3 and decrease to very low levels on day 5. Mitogen-stimulated lymphocytes at 3 days contain intracellular levels of LT which are several logs higher than that detectable in unstimulated cells. This observation suggests that both the biosynthesis and secretion of lymphotoxin is governed by a regulatory control process(es).     

Allograft immunity in vitro: V. Generation of cytotoxic effector cells in mixed lymphocyte culture and the specificity of target cell lysis

Cells from one-way mixed lymphocyte cultures lyse allogeneic target cells in vitro. Target cell lysis is effected by lymphoid cells; macrophages do not contribute to cell death to any measurable degree. The cytotolytic effect is detected at the earliest on the 4th culture day, and reaches a maximum on Day 10–12, i.e., considerably later than the peak of cell proliferation. On Day 6 the killer cell is a large cell (blast); later it is a small (lymphocyte). No cytotoxic effect is detected if DNA synthesis and cell division are blocked. Killer cells are not damaged during the lytic reaction. Direct cell-to-cell contacts rather than diffusable factors of long range, such as lymphotoxins, are prerequisites for target cell damage. Target cell lysis is specific. Labeled “third party” target cells, not sharing antigens with the stimulating cell, are not damaged.     

Internalization of alpha 2 macroglobulin in receptosomes. Studies with monovalent electron microscopic markers

Previous studies using multivalent, peroxidase-labeled antibody for localization of α₂ M have demonstrated that the binding of α₂-macroglobulin (α₂ M) to randomly distributed receptors on the surfaces of fibroblasts initiates the accumulation of α₂ M-receptor complexes in clathrin-coated pits. The α₂ M-receptor complexes are then internalized into a specialized vesicle termed the receptosome. In the present study we have used three different monovalent ligands to localize α₂ M and show that the endocytosis of α₂ M-receptor complexes by the receptosomal pathway is not initiated as a result of antibody-induced cross-linking of the α₂ M-receptor complexes. To perform these studies the following monovalent markers of α₂ M were prepared for electron microscopic visualization: (1) a monovalent hybrid antibody directed against α₂ M and ferritin; (2) a monovalent hybrid antibody directed against α₂ M-peroxidase; and (3) a direct 1:1 conjugate of α₂ M-peroxidase. We find that all three of the markers are internalized by the ligand pathway previously described using multivalent labels. The steps involved are clustering of α₂ M receptor complexes in coated regions of the plasma membrane followed by endocytosis of α₂ M into receptosomes. Our results are contrasted with previous studies on lymphocytes in which antibody induced cross-linking of membrane antigens was necessary for triggering their pinocytosis. The methods described in this paper are applicable for visualizing at the electron microscopic level the internalization of other ligands and hormones.     

In vitro depression of cellular immunity by Friend virus leukemic spleen cells.

Four distinct sublines of mouse L 929 cells (termed alpha, beta, gamma, and delta) were derived and shown to differ markedly in their in vitro sensitivity to human lymphotoxin (LT). The alpha L cell is most sensitive and is rapidly destroyed by very low dilutions of LT. This cell is 100 times more sensitive to LT than the most resistant (delta) L cell. The highly lymphotoxin-sensitive alpha cell makes it possible to reproducibly detect LT activity in as little as 0.0005 ml of supernatant medium. Additional studies revealed a direct correlation between the sensitivities of the four L cell sublines to LT and to direct cytolysis mediated by mitogen-stimulated human lymphocytes. The alpha, beta, gamma, and delta L cells were shown to be equally sensitive to antibody-mediated complement-dependent lysis, indicating that the sequence of sensitivities of these L cell sublines to the direct lymphocyte and to LT does not merely reflect a general susceptibility to cell destruction. These results lend further support to the view that lymphotoxin is an important mediator of in vitro target cell destruction by human effector lymphocytes.     

Formation of heterophile antibodies by human tonsilar lymphocytes: II. In vitro stimulation with allogeneic cells

Short-term cultures of human tonsilar lymphocytes (HTL), 5 × 10⁶ cells/culture, in medium RPMI 1640 supplemented with human group AB serum were studied for the production of plaque-forming cells (PFC) against sheep (SRBC) and bovine (BRBC) red blood cells following in vitro stimulation by various allogeneic lymphoid cells. Of 55 HTL specimens examined, 48 produced a significant number (50–300/culture) of PFC against SRBC and/or BRBC following the in vitro stimulation. The optimal doses of the stimulator HTL and peripheral blood lymphocytes (PBL) were 10⁷ and 5 × 10⁶/culture, respectively. After the stimulation, PFC appeared in significant numbers on the third day, reached the peak number on the sixth day, and decreased sharply in number thereafter. Removal of E-rosetting cells from both stimulator and responder populations abolished the PFC formation. PFC formation against SRBC was inhibited by solubilized Forssman antigen, while PFC formation against BRBC was inhibited strongly by Hanganutziu-Deicher antigen, hardly by Paul-Bunnell antigen and not at all by Forssman antigen. Supernatants of mixed lymphocyte culture of PBL were shown to enhance PFC formation of HTL cultures stimulated by allogeneic lymphocytes. The results of this study indicated that in vivo primed B cells of the HTL were triggered in vitro by allogeneic stimulation for the heterophile antibody formation. Since these antibodies are apparently directed against Forssman and Hanganutziu-Deicher antigens, the “allo” nature of these antigens as well as their relationship to the previously described heterophile transplantation antigens have to be clarified.