Adoptive transfer of experimental allergic encephalomyelitis: incubation of rat spleen cells with specific antigen.

Spleen cells from myelin basic protein (BP)-sensitized donor rats appear to be incapable of adoptively transferring experimental allergic encephalomyelitis (EAE) directly to normal recipients. It has been reported that in vitro incubation with concanavalin A (Con A) activates rat spleen cells so that they are capable of transferring EAE. We report here that incubation with specific antigen, BP, also permits transfer of disease with spleen cells. Data are presented in which activation of EAE spleen cells by Con A is compared with activation by BP. Cellular proliferation does not appear to be necessary for in vitro activation with specific antigen.     

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.     

Transfer of allergic encephalomyelitis with spleen cells from donors sensitized with myelin basic protein in incomplete Freund's adjuvant

Myelin basic protein (BP) emulsified in incomplete Freund's adjuvant (BP/IFA) is relatively nonencephalitogenic in Lewis rats. Furthermore, repeated injections of BP/IFA prevent subsequent induction of experimental allergic encephalomyelitis (EAE) by BP emulsified in complete Freund's adjuvant (BP/CFA). In spite of this, spleen cells from rats injected repeatedly with BP/IFA transfer EAE after they are cultured with BP almost as effectively as BP/CFA spleen cells. However, unlike the latter, BP/IFA spleen cells do not proliferate in response to BP in culture. Furthermore, BP/IFA spleen cells are unable to transfer EAE after culture with concanavalin A (Con A), in contrast to BP/CFA spleen cells. Both populations of spleen cells undergo a strong proliferative response to Con A in culture. For BP/IFA cells, at least, a proliferative response to BP in vitro is not a prerequisite for enhanced transfer of EAE in Lewis rats.     

Autoimmune effector cells. III. Role of adjuvant and accessory cells in the in vitro induction of autoimmune encephalomyelitis

The present investigation shows that autoreactive effector cells that transfer experimental allergic encephalomyelitis (EAE) can be activated from spleens and lymph nodes of Lewis rats given a single injection of 25 micrograms myelin basic protein (BP) in incomplete Freund's adjuvant (IFA), despite the fact that the cell donors do not develop EAE. Rather, these donor rats are unresponsive to EAE when given an encephalitogenic emulsion of BP in complete Freund's adjuvant (CFA). Lymphoid cells from rats given a single injection of BP-IFA were almost as effective as cells from BP-CFA-treated rats with respect to transferring EAE after in vitro activation with BP or concanavalin A (Con A). Irrespective of whether donors received BP in IFA or CFA, BP-cultured spleen and lymph node cells (SpC and LNC, respectively) transferred EAE, whereas Con A-cultured SpC but not LNC exhibited effector cell activity. Con A-cultured LNC were able to transfer EAE if the cultures were reconstituted with irradiated adherent phagocytic cells (which could be obtained from normal Lewis rat spleens) or with conditioned medium from these adherent SpC. These findings indicate that accessory cells are required for in vitro induction of this T cell-mediated autoimmune response.     

Cellular transfer of experimental allergic encephalomyelitis in Lewis rats: Effects of different sensitization regimens on in vitro reactivity of donor spleen cells to concanavalin A

Splenocytes from Lewis rats sensitized to guinea pig spinal cord (GPSC) and complete Freund's adjuvant (CFA) or to myelin basic protein (MBP)-CFA plus pertussis vaccine were less effective than spleen cells from MBP-CFA sensitized donors in transferring EAE to syngeneic recipients following culture with concanavalin A (Con A). Moreover, splenocytes from rats sensitized to GPSC-CFA plus pertussis vaccine showed no EAE transfer activity following culture with Con A. Diminished EAE transfer activity occurred in parallel with decreased proliferative responses of primed splenocytes to Con A. These effects were due, at least in part, to the use of pertussis vaccine and to Con A activation of a suppressive adherent cell subpopulation in sensitized donor spleens. Proliferative responses and EAE transfer activity were restored upon removal of plastic-adherent cells from splenocytes of rats sensitized to MBP-CFA plus pertussis vaccine prior to Con A activation of the non adherent lymphoid cells. Deletion of plastic-adherent cells from splenocytes of donors sensitized to GPSC-CFA plus pertussis vaccine prior to activation with Con A, however, had no effect on proliferative responses or EAE transfer activity. Furthermore, EAE transfer activity of Con A-activated splenocytes from MBP-CFA-sensitized donors was lost when such cells were cultured with splenocytes from donors sensitized to GPSC-CFA plus pertussis vaccine.     

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.     

Autoimmune effector cells. IV. Induction of experimental allergic encephalomyelitis in Lewis rats without adjuvant

Experimental autoimmune encephalomyelitis (EAE) was induced in Lewis rats without the aid of adjuvant. Radioresistant cells were activated from spleens of nonimmune donor rats by in vitro culture with myelin basic protein (BP). After adoptive transfer, these cells recruited EAE effector cells in normal syngeneic recipients, as demonstrated after transfer to secondary hosts. The induction of EAE without adjuvant may lead to a better understanding of the mechanisms of autoimmune disease induction.     

Adoptive transfer of experimental allergic encephalomyelitis with activated spleen cells: Comparison of in vitro activation by concanavalin A and myelin basic protein

Adoptive transfer of experimental allergic encephalomyelitis (EAE) was carried out in Lewis rats using splenic lymphocytes incubated in vitro with either concanavalin A (Con A) or myelin basic protein (MBP). Requirements were established for sensitization of donors, culture conditions, numbers of transferred cells, and incubation period of EAE in recipients. These were strikingly similar whether Con A or MBP was used. In addition, cellular proliferation in vitro was not required in either system, but proliferation after transfer to the recipient was essential for the development of clinical signs and histological lesions. These methods have potential value for analyzing mechanisms of immune induction in this classic model of autoimmune disease.     

Adoptive transfer of experimental allergic encephalomyelitis: requirement for macrophages in activation of spleen cells in vitro by concanavalin A or myelin basic protein

Adoptive transfer of experimental allergic encephalomyelitis (EAE) in Lewis rats is markedly enhanced when sensitized spleen cells are incubated in vitro with either concanavalin A (Con A) or myelin basic protein (MBP). This phenomenon permits more detailed analysis of the inductive phase of EAE than has heretofore been possible. We have now demonstrated that macrophages are essential for the process to occur, and that they probably act by different means depending on whether activation is carried out with the mitogen or the specific antigen. Depletion of macrophages by passage through G-10 Sephadex columns prevented activation of spleen cells by either Con A or MBP. The effect of Con A could be partially restored with 2-mercaptoethanol, while activation by MBP could not. Reconstitution of macrophage-depleted cultures with peritoneal exudate cells from either immune or normal rats fully restored activation by both Con A and MBP. Supernatants taken from spleen cell cultures were unable to restore the transfer activity of macrophage-depleted cells, indicating that activation probably is not mediated by a soluble factor released by macrophages. Depletion of macrophages after incubation with Con A slightly reduced transfer activity, but depletion after incubation with MBP abolished it. Thus the mechanisms of activation appear to differ in the two systems, and in the case of MBP the macrophage-mediated portion of the process may be incomplete prior to adoptive transfer.     

Lymphocytes from SJL/J mice immunized with spinal cord respond selectively to a peptide of proteolipid protein and transfer relapsing demyelinating experimental autoimmune encephalomyelitis.

Relapsing experimental autoimmune encephalomyelitis (R-EAE) can be induced in SJL/J mice by immunization with spinal cord homogenate and adjuvant. The specific Ag(s) responsible for acute disease and subsequent relapses in this model is unknown. Myelin basic protein (BP), an encephalitogenic peptide of BP (BP 87-99), and proteolipid protein (PLP) can each induce R-EAE in SJL/J mice, and a peptide of PLP (PLP 139-151) has been reported to induce acute EAE. To determine the encephalitogens in cord-immunized mice with R-EAE, the in vitro proliferative responses of lymph node cells (LNC) and central nervous system mononuclear cells to BP, BP peptides, and PLP peptides were examined during acute EAE and during relapses. LNC responded only to PLP peptides 139-151 and 141-151 and did not respond to BP or its peptides during acute or chronic disease. Central nervous system mononuclear cells also preferentially responded to PLP 139-151 and 141-151 during acute and relapsing disease. A PLP 139-151 peptide-specific Th cell line was selected from LNC of cord-immunized donors. Five million peptide-specific line cells transferred severe relapsing demyelinating EAE to naive recipients. We conclude that PLP peptide 139-151 is the major encephalitogen for R-EAE in cord-immunized SJL/J mice. We demonstrate for the first time that Th cells specific for this peptide are sufficient to transfer relapsing demyelinating EAE. The predominance of a PLP immune response rather than a BP response in SJL/J mice suggests that genetic background may determine the predominant myelin Ag response in human demyelinating diseases such as multiple sclerosis.     

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.     

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.     

Enhanced transfer of experimental allergic encephalomyelitis with strain 13 guinea pig lymph node cells: requirement for culture with specific antigen and allogeneic peritoneal exudate cells

Previously, we reported that transfer of experimental allergic encephalomyelitis (EAE) with sensitized peritoneal exudate cells (PEC) in strain 13 guinea pigs is markedly enhanced if the cells are first cultured with specific antigen, myelin basic protein (BP). These cells also undergo considerable antigen-specific proliferation. In contrast, the data reported here show that lymph node cells (LNC) from sensitized animals display neither enhanced transfer nor antigen-specific proliferation after culture with BP. Enhanced transfer is obtained, however, if a second nonspecific signal is available. This second signal is provided by the presence of normal allogeneic strain 2 PEC in culture. After culture with BP and strain 2 PEC, 2.5 to 5 x 10(7) strain 13 LNC transfer disease reproducibly, in contrast with approximately 1 x 10(9) previously required for successful transfer. Addition of allogeneic or syngeneic PEC without antigen does not lead to enhanced transfer by LNC. Culture with normal syngeneic PEC plus BP oly infrequently enhances transfer by LNC. The intense mixed lymphocyte reaction (MLR) induced by addition of strain 2 PEC to strain 13 LNC precludes the use of 3H-TdR incorporation for detection of proliferation by EAE effector cells. However, inhibition of transfer with low doses of mitomycin C (2 to 5 micrograms/ml) pluse the fact that EAE effector cells are found almost exclusively in the light fraction of BSA gradients after (but not before) culture suggests that the latter are induced to proliferate in culture.     

Autoimmune effector cells. VIII. Cellular requirements for the induction of autoreactive T cells of experimental allergic encephalomyelitis in nonimmune rats

We utilized a system of sequential in vitro cell culture and adoptive transfer to investigate the sequence of events which lead to the activation of effector cells responsible for the induction of experimental autoimmune encephalomyelitis (EAE) in Lewis rats. This procedure involves only naive (nonimmune) rats, and eliminates the requirement for adjuvants. Spleen cells (SpC) from naive donors were sensitized in vitro to myelin basic protein (BP), then transferred to intermediate (primary) hosts. Although these recipients did not develop EAE, they were primed for disease because they exhibited accelerated onset of active EAE when challenged with BP in adjuvant. Moreover, SpC from nonchallenged primary recipients transferred EAE to secondary recipients subsequent to in vitro exposure to antigen. The cells from the naive cultures which primed the intermediate recipients were radioresistant (1500 R); other studies have indicated that these are macrophages. In contrast, the cells which transferred EAE to the secondary recipients were radiation-sensitive T lymphoblasts. The finding that these cells also elicit disease in lethally irradiated (850 R) secondary recipients suggests that the transferred cells either are the actual effector cells of EAE or induce disease in collaboration only with radioresistant host cells.     

Adoptive transfer of experimental allergic encephalomyelitis in SJL/J mice after in vitro activation of lymph node cells by myelin basic protein: requirement for Lyt 1+ 2- T lymphocytes

Optimal conditions were established for the adoptive transfer of experimental allergic encephalomyelitis (EAE) in SJL/J mice. Lymph node cells from SJL/J mice primed in vivo with myelin basic protein (BP) were incubated in vitro with BP. These cells proliferated specifically to BP and when transferred at the optimal conditions into syngeneic mice induced EAE in 100% of the recipients. The in vitro proliferative response to BP was dependent on the presence of Lyt 1+ 2- T lymphocytes. Furthermore, when the activated LNC were treated before transfer with anti-Thy 1 or anti-Lyt 1 antibody and C, neither clinical nor histologic signs were observed in the recipients, whereas treatment with anti-Lyt 2 antibody and C had no effect. These results indicated that Lyt 1+ 2- T cells are responsible for the transfer of EAE.     

Immunoregulation of experimental allergic encephalomyelitis: conditions for induction of suppressor cells and analysis of mechanism.

We determined requirements for the induction of immunoregulatory suppressor cells in experimental allergic encephalomyelitis (EAE) in Lewis rats. Pretreatment of rats with myelin basic protein (BP) in incomplete Freund's adjuvant (IFA) stimulates the proliferation of suppressor cells that localize in lymph nodes and spleen (but not thymus) and exert control over the development of clinical EAE. Dosage studies revealed that 3 X 10(7) suppressor cells can adoptively transfer suppression to syngeneic recipients. Transferred unresponsiveness wanes within 3 weeks, indicating that the suppressor cells are short-lived lymphocytes, although actively induced unresponsiveness persists for at least 8 weeks, probably as a result of continual proliferation under the influence of antigen. No evidence was obtained to suggest that antigen carry-over or blocking antibody production accounts for adoptive transfer of unresponsiveness. Suppressor cells apparently act at the inductive phase of the immune response since they had no inhibitory effect on adoptive transfer of disease by effector lymph node cells. Other mechanisms also may play a role in unresponsiveness to EAE, since rats pretreated i.v. with high dosages of soluble BP were temporarily rendered unresponsive, although suppressor cells could not be detected in these animals.     

The nature of the defect in experimental allergic encephalomyelitis (EAE)-resistant Lewis (Le-R) rats

Recently, a colony of Lewis rats has been described which is resistant to experimental allergic encephalomyelitis (EAE). These rats, termed Le-R, are still histocompatible with other Lewis rats. The genetic defect which results in EAE-resistance was shown not to be linked to the RT1.B (Ir) region of the MHC. Myelin basic protein (BP)-sensitization of Le-R rats induces cells capable of mounting a proliferative response to BP in culture but incapable of transferring EAE after culture with BP. The present study demonstrates that the latter deficiency can be overcome either by incorporating lipopolysaccharide (LPS) in the BP-culture medium or by simultaneous transfer of LPS-activated antigen-nonspecific spleen cells with the BP-sensitized cells. The BP-sensitized Le-R cells fail to transfer EAE due to their inability to initiate lesions in the CNS. LPS, working through an antigen-nonspecific cell or cell products, can correct the defect in the Le-R cells such that the antigen-specific cells become capable of initiating CNS lesions which lead to development of clinical EAE.     

Detection of autoimmune cells proliferating to myelin basic protein and selection of T cell lines that mediate experimental autoimmune encephalomyelitis (EAE) in mice

A procedure is described for the detection of an in vitro proliferative response to the autologous mouse myelin basic protein in mice injected with mouse spinal cord homogenate (MSCH) or with myelin basic proteins (BP) of mouse (MBP) or rat (RBP) origin. The administration of MSCH, but not of MBP or RBP, in a suitable adjuvant could produce a reproducible clinical disease. Nevertheless, a proliferative response to the autologous MBP could not be detected after either inoculation. Only the removal of the adherent cell fraction from the immunized cell population and its replacement with fresh naive accessory cells could reveal a proliferative response to the autologous MBP and to the heterologous RBP. A heteroclitic cross-reactivity between MBP and RBP is demonstrated. The possibility of detecting an in vitro proliferative response to BP allowed the selection and propagation in vitro of cells specific to BP. T cell lines were established that specifically proliferated in response to BP and mediated EAE in normal mice. Intravenous inoculation of as few as 10(6) line cells was capable of producing clinical signs of EAE in normal recipients within 5 to 6 days. Thus, although an inoculation of MSCH was required for active induction of the disease, T cells specifically reactive against BP are sufficient for mediation of EAE in mice.     

Adoptive transfer of experimental allergic encephalomyelitis: conditions influencing memory and effector cell development.

The cellular transfer of clinical experimental allergic encephalomyelitis (EAE) with immune spleen cells is only accomplished following lymphoid cell stimulation during an intervening in vitro culture activation period. Recipients of these cells recover from the ensuing adoptively transferred paralytic episode and subsequently respond to active challenge with myelin basic protein (BP)-CFA in an accelerated time frame consistent with the presence of memory cells in the initial cell transfer inoculum. We have found that the addition of anti-CD4 antibody or dexamethasone during the activation period inhibits the development of the transfer active EAE effector cell subpopulation, but does not alter the in vitro development and subsequent expression of the BP-specific memory cell subpopulation. Additional experiments also suggest the development of memory cells in the absence of effector cell activity. PMA + ionomycin when used as a stimulus during the culture activation period leads to effector and memory cell development. The stimulation response is dose dependent, in that a reduced concentration of PMA + ionomycin does not lead to EAE effector cell development; however, at these reduced levels of PMA + ionomycin, memory cell development still occurred. Additional evidence which supports the concept of independent development of memory cells and effector cells was obtained with a BP-specific cell line. Following recovery from cell line-mediated clinical EAE, as well as following adoptive transfer of the cell lines in the precursor stage, cell recipients did not develop an early onset of active EAE when subsequently immunized with BP-CFA. Thus the BP-specific T-cell line appears to contain the precursors of the effector cell subpopulation but does not appear to contain the BP memory cell subpopulation. Collectively these observations suggest the existence of distinct T-cell subsets or pathways of development that are followed during the response to BP as measured by the development of clinical EAE.     

Experimental allergic encephalomyelitis in Lewis rats: inhibition by bacterial lipopolysaccharides and acquired resistance to reinduction by challenge with myelin basic protein

In 2-mo-old Lewis rats immunized with bacterial lipopolysaccharides (LPS) precomplexed to guinea pig myelin basic protein (BP), the clinical and histologic manifestations of experimental allergic encephalomyelitis (EAE) were diminished compared with BP-treated controls. Similarly, in animals immunized with BP and challenged with BP-LPS at the same time or as long as 5 days after, the immunization with BP also inhibited the disease. That this capacity to reduce the incidence of BP-induced EAE is a unique property of LPS was suggested by the fact that other negatively charged molecules, such as DNA, RNA, and dextran sulphate, were not effective in inhibiting the clinical signs of EAE. After recovery from EAE induced by BP, some animals develop a recurrence of the disease if challenged with BP at appropriate intervals. However, after recovery from mild EAE induced by BP-LPS and after challenges with EAE-initiating BP antigens, secondary EAE was inhibited significantly.