Regulation of experimental autoimmune encephalomyelitis in the C57BL/6J mouse by NK1.1+, DX5+, alpha beta+ T cells

C57BL/6 (B6) mice with targeted mutations of immune function genes were used to investigate the mechanism of recovery from experimental autoimmune encephalomyelitis (EAE). The acute phase of passive EAE in the B6 mouse is normally resolved by partial recovery followed by mild sporadic relapses. B6 TCR beta-chain knockout (KO) recipients of a myelin oligodendrocyte glycoprotein p35-55 encephalitogenic T cell line failed to recover from the acute phase of passive EAE. In comparison with wild-type mice, active disease was more severe in beta(2)-microglobulin KO mice. Reconstitution of TCR beta-chain KO mice with wild-type spleen cells halted progression of disease and favored recovery. Spleen cells from T cell-deficient mice, IL-7R KO mice, or IFN-gamma KO mice were ineffective in this regard. Irradiation or treatment of wild-type spleen cell population with anti-NK1.1 mAb before transfer abrogated the protective effect. Removal of DX5(+) cells from wild-type spleen cells by anti-DX5 Ab-coated magnetic beads before reconstitution abrogated the suppressive properties of the spleen cells. TCR-deficient recipients of the enriched DX5(+) cell population recovered normally from passively induced acute disease. DX5(+) cells were sorted by FACS into DX5(+) alpha beta TCR(+) and DX5(+) alpha beta TCR(-) populations. Only recipients of the former recovered normally from clinical disease. These results indicate that recovery from acute EAE is an active process that requires NK1.1(+), DX5(+) alpha beta(+) TCR spleen cells and IFN-gamma.     

Regulation of experimental allergic encephalomyelitis. II. Appearance of suppressor cells during the remission phase of the disease

Lewis rats are susceptible to experimental autoimmune encephalomyelitis (EAE). Most rats recover from paralysis and are subsequently resistant to the disease. In an adoptive transfer system, we found that lymph node cells (LNC) from rats that had recovered from EAE protect syngeneic recipients from the disease when the latter are challenged with encephalitogenic myelin basic protein and adjuvant after receiving donor cells. Suppression is antigen-specific and requires viable LNC. In contrast to the suppressor cells we previously studied in tolerized rats, which were nonadherent T lymphocytes, the suppressor cells found in rats that have recovered from EAE adhere to glass wool. However, they are not retained on Sephadex G-10 columns to which macrophages adhere. Suppressor activity is enriched in the nylon wool-adherent LNC population (which consists of approximately 80% Ig+ cells). Our findings suggest that activation of adherent suppressor cells may be implicated in recovery from EAE. These may be adherent T cells, or B cells that produce anti-BP blocking antibodies.     

Immediate, long-lasting suppression of autoimmune encephalomyelitis by cell-bound neuroantigen

When lymphoid cells from rats recovered from experimental autoimmune encephalomyelitis (EAE) were incubated in vitro for 1 hr with myelin basic protein (BP), then washed and transferred along with anti-BP immune serum to naive recipients, those recipients immediately developed a solid, long-lasting resistance to active induction of EAE. To obtain this high level of suppression, both steps of BP-incubation of cells and transfer of immune serum were found to be essential, i.e., direct transfer of nonincubated cells plus immune serum had no comparable suppressive effect, nor had transfer of BP-incubated cells with nonimmune serum. Specificity of the suppressive effect was indicated by the finding that cells from BP-sensitized donors, incubated with BP, protected against BP-CFA-induced disease but not against disease induced with whole spinal cord homogenate (SCH-CFA). As expected, cells from SCH-CFA-sensitized donors incubated with SCH protected recipients against disease induced with either SCH-CFA or BP-CFA. The suppression appears to act early in the afferent stage of the immune response, since inoculation with incubated cells as little as 24 hr after active challenge was ineffective. There was no suppression of passively induced disease.     

Experimental allergic encephalomyelitis in mice: Adoptive transfer of disease is modulated by the presence of natural suppressor cells

Normal, untreated syngeneic recipients of lymphocytes from mice with experimental allergic encephalomyelitis (EAE) do not generally express adoptively transferred disease. Cell transfer of EAE is more successful when syngeneic recipients are treated with cyclophosphamide (CY) prior to the injection of donor cells. Normal, untreated recipients that do not develop EAE after receiving EAE donor lymphocytes are also unresponsive to subsequent encephalitogenic challenge. Those CY-treated recipients that fail to develop EAE after cell transfer do develop EAE after subsequent challenge. After reconstitution with normal splenic lymphocytes, CY-treated recipients do not develop EAE after subsequent challenge. These findings suggest the presence of an intrinsic natural suppressor cell subpopulation in naive mice which modulate the expression of adoptively transferred T lymphocytes.Special Issue dedicated to Dr. Elizabeth Roboz-Einstein.     

Recipient contributions to serial passive transfer of experimental allergic encephalomyelitis

EAE can be adoptively transferred into normal recipients by the transfer of BP-specific EAE effector cells. After cell transfer, a series of ill-defined events occur in the recipient that culminate in the development of paralysis associated with neural tissue damage. We investigated the subsequent recipient response to the adoptively transferred disease and examined the role that recipient lymphocytes play in the development of adoptively transferred EAE. Recipient involvement was assessed by the transfer of EAE through a series of normal F1 animals as recipients and at the endpoint of the experiment, determining the MHC restriction pattern of the BP-sensitive cells present. The serial transfer of EAE from BP-CFA-sensitized LEW----(LEW X F-344)F1----(LEW X P2)F1, and from BP-CFA sensitized LEW----(LEW X F344)F1----(LEW X F-344)F1, resulted in the development of BP-sensitive cells in the spleens of the secondary recipients that were able to transfer disease into normal LEW recipients. To test directly for the development of host-derived BP-sensitive cells that might arise in the F1 animal, the serial transfer of EAE from LEW----(LEW X ACI)F1----(LEW X ACI)F1 was performed. When BP-sensitive cells obtained from the secondary (LEW X ACI)F1 recipient animal were transferred into either normal LEW and ACI, or irradiated LEW and ACI animals as final recipients, transfer of disease was successful only into the LEW parental. These results suggest that the development of passive EAE is due solely to the transferred BP-sensitive cells originating from the actively immunized donor, and that no host-derived lymphocytes are recruited into the pool of EAE effector precursor cells found in the spleen of animals after the development of adoptively transferred EAE.     

The role of mast cells in the elicitation of experimental allergic encephalomyelitis

Experimental allergic encephalomyelitis (EAE), a T cell-mediated autoimmune disease can be transferred with lymphoid cells from actively immunized rats into naive recipients. In the mouse, previous studies have suggested a role for histamine/serotonin in the development of active EAE. We have found that myelin basic protein-reactive cells transfer a biphasic skin test response to naive rats analogous to what has been described in the mouse contact dermatitis system, where mast cell sensitization by Ag-specific T cell factors is required for the induction of skin test responses. Treatment of cell recipients with the serotonin receptor antagonists, cyproheptadine or methysergide, blocked or significantly reduced the development of EAE. Furthermore, it was found that treatment with cyproheptadine was effective in blocking clinical disease when administered day 3 to day 6 after cell transfer. In contrast, cyproheptadine treatments before induction of paralysis day 0 to 3, failed to alter the course of clinical disease. The inhibitor of mast cell degranulation, proxicromil, was also found to effectively block the elicitation of adoptively transferred EAE and was also found to be effective when administered just before the onset of clinical disease. Reserpine, a compound known to deplete mast cells of vasoactive amines by forcing granule contents into the cytoplasm where they are degraded by cell enzymes, was also effective in blocking both active and adoptively transferred EAE. Disease inhibition was found to be partially reversed with pargyline, an inhibitor of monoamine oxidase. In addition lymphocytes from treated animals were capable of transferring disease to naive recipients and appeared to have normal activity as assessed by Ag-or mitogen-driven proliferation in addition to IL-2 production.     

Passive transfer of experimental allergic encephalomyelitis in the Lewis rat with activated spleen cells: differential activation with mitogens

It has previously been shown that spleen cell transfer of clinical EAE requires donor cells to be cultured in vitro prior to transfer. Donor cells must be stimulated when cultured, and either Con A or the encephalitogen, guinea pig myelin basic protein (BP), satisfies this stimulation requirement. Following recovery from passive disease, recipients of these in vitro cultured cells will subsequently develop clinical symptoms of EAE sooner than controls when challenged with BP in complete Freund's adjuvant (BP-CFA). In the present study, three T-cell mitogens were evaluated as donor cell stimulants in the required in vitro culture period. Pokeweed mitogen (PWM) as well as Con A stimulated the donor cell population to the degree that clinical EAE could be transferred with 5 × 10⁶ cultured viable cells. Con A at culture levels below 0.25 μg/ml did not yield transfer active cells even though proliferation levels were similar to those found at concentrations of Con A that did yield transfer active cells. Phytohemagglutinin (PHA)-stimulated cultures did not transfer clinical disease even though the degree of lectin induced proliferation ([³H]thymidine uptake as well as recovered cells from culture) was equivalent to the PWM- or Con A-stimulated, transfer positive, cultures. Mixing experiments suggested that the inability of PHA or low doses of Con A to induce transfer active cells was not due to the induction of suppressor cells. Although cells cultured with PHA do not transfer clinical EAE, recipients of these cells as well as recipients of either PWM- or Con A-stimulated donor cells develop an early appearance of disease upon subsequent challenge with BP-CFA. This included cells incubated with a concentration of Con A (0.1 μg/ml) which did not induce cells capable of transferring clinical EAE. These results suggest that PHA and perhaps the low dose of Con A may stimulate the proliferation of the EAE effector cell precursor population without causing the additional differentiation of this precursor population into the effector cell population which is capable of transferring clinical disease. Alternatively, PHA may expand only the helper cell population while effective doses of Con A and PWM would expand both helper and effector cell populations.     

T cell requirement for experimental allergic encephalomyelitis induction in the rat.

The question of whether a cell-mediated or a humoral mechanism initiates EAE in rats sensitized with BP-CFA was investigated. The requirement of T cells for EAE induction was manifested when Tx, irradiated rats were reconstituted with normal lymphoid cells treated with ATS and then injected with BP-CFA. Neither EAE nor antibody was produced, indicating the T cell dependency of BP specific antibody production. More precise information regarding the role of the T cell in the production of EAE was obtained by means of passive transfer of EAE with sensitized lymphocytes. Thus, transfer of lymphoid cells from rats previously sensitized to BP-CFA into Tx, irradiated rats elicited EAE and antibodies to BP. However, no EAE followed when the transferred cells were first depleted of T cells by treatment with ATS. Nevertheless, ATP pretreatment did not depress the levels of antibody to BP produced in the transfer recipients. The latter finding indicates that the cells from animals sensitized 9 days previously were already committed to the production of antibodies to BP. Therefore, a) T cells are absolutely necessary for induction of EAE and b) antibody detected by antigen-binding is not responsible for the pathogenesis of this disease.     

Antigen-specific inhibition of immune interferon production by suppressor cells of autoimmune encephalomyelitis

Previous work from this laboratory has revealed that spleen and/or lymph node cells from Lewis rats, that have recovered from an acute episode of experimental autoimmune encephalomyelitis (EAE), suppress the development of EAE when injected into syngeneic recipients subsequently challenged with myelin basic protein (MBP) in CFA. In an effort to understand the mechanism of this suppression, we measured the production of immune IFN-gamma, which may be required for the induction of an immune response, by EAE effector T cells (which transfer disease) and EAE suppressor cells when cultured in vitro with MBP. We now report that EAE effector T cells produce IFN-gamma when cultured in vitro with MBP. In contrast, spleen cells from recovered rats (which manifest suppressor activity in vivo) do not produce IFN-gamma. Moreover, in cell mixing experiments, these suppressor spleen cells inhibited the production of IFN-gamma by EAE effector cells. This inhibition was not eliminated by the removal of macrophages nor by the inhibition of PG synthesis by indomethacin. Furthermore, the inhibition was shown to be Ag-specific and mediated by nylon-adherent, radiation-sensitive splenic T cells. The findings suggest that suppressor cells regulate EAE by inhibiting IFN-gamma production by effector cells. This inhibition may result in the down-regulation of IFN-gamma-induced expression of class II major histocompatibility Ag on cells of the central nervous system, thus reducing the presentation of tissue-specific Ag (i.e., MBP) to autoreactive lymphocytes.     

A quantitative immunohistochemical comparison of actively versus adoptively induced experimental allergic encephalomyelitis in the Lewis rat

A quantitative immunohistochemical comparison of actively and adoptively induced experimental allergic encephalomyelitis (EAE) in the Lewis rat was performed. Since the methods of EAE induction of these two systems and the kinetics of disease appearance are different, while the histopathology, disease manifestations, duration, and severity are similar, this study sought to identify any differences which exist at the level of the target organ. The number of cells expressing the T helper (W3/25) or suppressor/cytotoxic (OX-8) phenotypes and the number of Ia-positive cells found in the spinal cord of animals given EAE by one of the two methods were compared at two time points at which maximal similarities should exist. The results show that during acute adoptively induced EAE the inflammatory infiltrate contains a larger number of T helper (TH) cells per unit area than in acute active EAE. With the resolution of clinical signs of EAE, the disappearance of cells from the spinal cord is more rapid in adoptive EAE. In contrast, the inflammatory infiltrate and Ia-positive parenchymal cells persist in active EAE following recovery. These results suggest that actively and adoptively induced EAE may differ with respect to the effector mechanisms and/or the mechanisms of recovery at the level of the target organ.     

LF 15-0195 inhibits the development of rat central nervous system autoimmunity by inducing long-lasting tolerance in autoreactive CD4 T cells

Experimental autoimmune encephalomyelitis (EAE) is a T cell-dependent autoimmune disease induced in susceptible animals by a single immunization with myelin basic protein (MBP). LF 15-0195 is a novel immunosuppressor that has been shown to have a potent immunosuppressive effect in several pathological manifestations. The purpose of this study was to investigate the effect of this drug on the induction and progression of established rat EAE and to dissect the mechanisms involved. We show that LF 15-0195 administration at the time of MBP immunization reduces the incidence and severity of EAE in Lewis rats. This drug also inhibits ongoing and passively induced EAE, indicating that LF 15-0195 affects already differentiated pathogenic lymphocytes. Compared with lymph node cells from untreated rats, lymphocytes from MBP-immunized rats treated with LF 15-0195 proliferated equally well in response to MBP in vitro, while their ability to produce effector cytokines and to transfer EAE into syngeneic recipients was significantly reduced. This phenomenon is stable and long-lasting. Indeed, neither IL-12 nor repeated stimulation with naive APC and MBP in vitro rendered MBP-specific CD4 T cells from protected rats encephalitogenic. In conclusion, LF 15-0195 treatment suppresses EAE by interfering with both the differentiation and effector functions of autoantigen-specific CD4 T cells.     

Two phenotypically distinct populations of T cells have suppressor capabilities simultaneously in the maintenance phase of immunologic enhancement

The events leading to immunologic enhancement in LEW rats immunized actively with Brown Norway (BN) rat spleen cells and passively with LEW anti-BN hyperimmune serum 11 and 10 days before receiving (LEW X BN)F1 cardiac allografts, respectively, have been studied. Cellular suppressor mechanisms developing during the induction phase of this phenomenon have recently been shown to be mediated by W3/25+ T cells in an antigen-specific manner. The present study suggests that the late maintenance phase of immunologic enhancement is mediated in vivo by simultaneously present separate donor-specific T cell subpopulations of W3/25+ and OX8+ phenotypes. Splenocyte subsets from grafted recipients greater than 100 days after transplantation were adoptively transferred into unmodified syngeneic LEW rats that received a specific test allograft 24 hr later, or into B recipients bearing indefinitely surviving heart grafts. Test graft survival was prolonged significantly in the first group and not altered in the second. Indeed, nonoverlapping W3/25+ and OX8+ cell fractions were separately responsible for suppression. However, when suppressor activity was tested in vitro in a three-component coculture mixed lymphocyte reaction, no suppression by T cells was obtained; this lack of correlation between in vivo and in vitro results has also been noted by other investigators in different systems. Thus, in the maintenance phase of actively and passively induced immunologic enhancement, interplay between two phenotypically distinct T cells with suppressor characteristics, but not putative cell-surface blocking factors, seems to prevent development of an alloreactive response and mediate host unresponsiveness.     

Adoptively transferred experimental autoimmune encephalomyelitis in SJL/J, PL/J, and (SJL/J x PL/J)F1 mice. Influence of I-A haplotype on encephalitogenic epitope of myelin basic protein

Guinea pig basic protein (GPBP)-immune lymph node cells (LNC) from SJL, PL, and SJL x PL (F1) mice proliferated to whole GPBP and GPBP fragments 1-37, 43-88, and 89-169. All three strains of mice developed experimental allergic encephalomyelitis (EAE) by active immunization with whole GPBP or by passive transfer of LNC cultured with whole GPBP. SJL (H-2s) and PL (H-2u) mice developed EAE by active immunization with fragments 89-169 or 1-37, respectively, or by passive transfer of LNC cultured with the same Ag. F1 mice developed EAE by active immunization only with fragment 1-37 or by passive transfer of LNC cultured with either of the above fragments. Removal of macrophages (MO) from immune-F1 LNC resulted in the loss of a proliferative response and the ability to transfer EAE. Reconstitution of MO-depleted immune F1 T cells with either F1-, SJL-, or PL-MO restored the proliferative responses to whole GPBP and the three fragments. Cultures of immune F1 T cells reconstituted with any of the three MO populations and incubated with whole GPBP passively transferred EAE into naive F1 mice. Immune F1 T cells cultured with F1 MO in the presence of either fragment 1-37 or 89-169 transferred EAE. F1 T cells cultured with SJL MO were able to transfer EAE only if the Ag was fragment 89-169, whereas F1 T cells cultured with PL MO were able to transfer disease only if incubated in the presence of fragment 1-37. F1 mice are passively susceptible to EAE induced by adoptive transfer of cells reactive to either the N-terminal or C-terminal fragment and that the encephalitogenic determinant of GPBP is related to the genome of MO present in vitro.     

Inhibition of allergic encephalomyelitis in rats by treatment with sulfated polysaccharides

A number of sulfated polysaccharides were tested for their ability to inhibit passively induced experimental allergic encephalomyelitis (EAE) in rats. Heparin and fucoidan both completely inhibited passive EAE even when treatment was begun 3 days after transfer of cells. Pentosan sulfate was partially inhibitory whereas chondroitin-4-sulfate had no effect. Inhibition was not merely due to killing of the cells since active sensitization 14 days after cell transfer resulted in an early onset of disease indicating the persistence of transferred cells as memory cells. Although all the inhibitory polysaccharides are anticoagulants, it would appear that this function alone is not the reason for inhibition since a heparin preparation devoid of anticoagulant activity also partially inhibited EAE. Actively induced EAE was also significantly delayed by treatment with heparin. The results are discussed in terms of the polysaccharides inhibiting the enzymatic dependent movement of lymphocytes across central nervous system vascular endothelium.     

Detection of the precursor and effector cells of experimental allergic encephalomyelitis in the thoracic duct of the rat

Despite strong evidence pointing to the fundamental role of the T cell in the pathogenesis of experimental allergic encephalomyelitis (EAE), little has been known about the normal traffic of the precursor (unprimed) and effector (primed) cells of EAE. We have demonstrated the recirculation of the precursor cells in that B rats regained their susceptibility to EAE following reconstitution with thoracic duct lymphocytes (TDL) passed through an irradiated intermediate host as well as following reconstitution with normal thymocytes or normal TDL. The effector cells were shown to be present in TDL in that TDL from donors immunized 11 or 12 days prior to transfer could passively transfer EAE to naive recipients.     

Effect of cyclophosphamide on suppressor cell activity in mice unresponsive to EAE.

Protection against experimental allergic encephalomyelitis (EAE) was induced in susceptible mice of (SJL/J X BALB/c)F1 hybrid, by injection of either mouse spinal cord homogenate, the small mouse basic protein, or Cop 1 in incomplete Freund's adjuvant, before EAE induction. It was demonstrated that the unresponsiveness induced by the three antigens is mediated by suppressor T cells residing in the spleen cell population and can be adoptively transferred to normal syngeneic recipients. Low dose of cyclophosphamide (20 mg/kg) administered 2 days before the encephalitogenic challenge abrogated the unresponsiveness to EAE and reverted the protected mice sensitive to disease induction. Cyclophosphamide was also active on adoptively transferred unresponsiveness, thus donors that had been treated with cyclophosphamide were unable to further transfer unresponsiveness to EAE. These results indicate the elimination by cyclophosphamide of suppressor cells that interfere with the effector mechanisms leading to EAE.     

Macrophages and nitric oxide as the possible cellular and molecular basis for strain and gender differences in susceptibility to autoimmune central nervous system inflammation

PVG rats are resistant to actively induced experimental autoimmune encephalomyelitis (EAE) and this appears to be directly related to high and sustained systemic levels of reactive nitrogen intermediates(RNI) following sensitization for EAE when compared to the highly susceptible Lewis rat. An apparent cellular basis for the different EAE susceptibility between the two rat strains is described. Spleens of PVG rats have increased monocyte/macrophage numbers(NO producing cells) and lower erythrocyte (NO scavengers) to nucleated spleen cell ratios compared with Lewis rats. Splenectomy demonstrated the pivotal role of the spleen in resistance to EAE as splenectomized PVG rats were rendered completely susceptible to disease induction.It was further demonstrated that EAE resistance in PVG rats is limited only to females and that only female PVG rats have increased splenic macrophage and an enhanced NO production following immunization. The males are fully susceptible to EAE and their spleen cell populations are similar to those of Lewis rats of either gender. Despite being resistant to active disease induction, immunized female PVG rats can generate EAE effector cells that are capable of passively transferring disease.Furthermore, female PVG rats are fully susceptible to passively transferred EAE. Thus, there appears to be no defect in the female PVG target tissue or in the processing or presentation of antigen,but a block at the level of effector cell expansion and/or recirculation and transmigration into the target tissue in actively induced EAE.     

Autoreactive T cells in mercury-induced autoimmunity. Ability to induce the autoimmune disease

It has been previously shown that autoreactive T cells appear during mercury-induced autoimmunity in Brown-Norway (BN) rats. In the present work, it is shown that: 1) T cells and T helper cells from HgCl2-injected BN rats are able to actively transfer autoimmunity in normal BN rats; the disease transferred is exacerbated when recipients are treated with the antisuppressor/cytotoxic T cell monoclonal antibody (OX8); 2) normal T cells preincubated with HgCl2 are also able to transfer the disease in OX8-treated but not in T cell-depleted rats; and 3) T cells from HgCl2-injected BN rats also transferred the disease in both normal and T cell depleted rats. It is concluded that: 1) autoreactive T cells, and presumably anti-Ia T cells are involved in the pathogenesis of mercury-induced autoimmunity; 2) these autoreactive T cells induce suppressor/cytotoxic T cells to proliferate in normal syngeneic recipients; the fact that this T cell subset did not proliferate in HgCl2-injected BN rats suggests that HgCl2 also affects T suppressor cells; and 3) mercury-induced autoimmunity could result from the additive effect of the emergence of autoreactive T cells and of a defect at the T suppressor level.     

The influence of cyclosporin A on the development of actively induced and passively transferred experimental allergic encephalomyelitis

The immunosuppressive effects of cyclosporin A (CsA) were tested on actively induced and passively transferred experimental allergic encephalomyelitis (EAE). Actively induced EAE could be inhibited if CsA was administered per os at 25 mg/kg/day but not at 10 mg/kg/day. Passive transfer of clinical EAE occurred in all cell recipients including those fed CsA at either 25 or 50 mg/kg/day. Cyclosporin A could inhibit the development of transfer active cells in vitro and in vivo, however, inhibition of transfer active populations by CsA required the presence of CsA during the initial stage of cell response. If CsA was added to Con A-stimulated spleen cell cultures after a delay of 24 hr then these cells transferred clinical disease. Similarly, animals fed CsA concurrently with basic protein sensitization did not develop cell populations capable of transferring EAE. If CsA feeding commenced 2 or 4 days following sensitization all basic proteinsensitized animals still failed to develop EAE; however these latter groups of animals were a suitable source of cells capable of transferring some signs of clinical EAE.     

The cellular basis of adjuvant arthritis. I. Enhancement of cell-mediated passive transfer by concanavalin A and by immunosuppressive pretreatment of the recipient

Two reliable systems for the cell-mediated passive transfer of adjuvant arthritis have been developed. Donor rats were sensitized with Mycobacterium butyricum in mineral oil. In the first system, intravenous injection of adjuvant-sensitized donor lymph node or spleen cells into adult-thymectomized, lethally irradiated, bone marrow cell-reconstituted syngeneic rats induced arthritis in the recipients. In the second system, adjuvant-sensitized donor lymph node or spleen cells were cultured in vitro with concanavalin A; these cells induced arthritis in normal recipients as well as in thymectomized, irradiated, bone marrow cell-reconstituted recipients. The passively transferred disease in both systems resembled classical adjuvant-induced arthritis clinically, radiographically, and histologically. Neither irradiated, adjuvant-sensitized donor cells nor cells from donors not injected with complete adjuvant could passively transfer arthritis.