Allogeneic restriction of the delayed inflammatory reaction in the rat.

Delayed-type hypersensitivity (DTH) to Listeria monocytogenes was measured in rats that were recipients of syngeneic, semisyngeneic, and allogeneic immune thoracic duct lymphocytes (TDL). DTH could be transferred only to recipients that shared at least one haplotype with the TDL donors. The restriction was expressed in an inability of sensitized lymphoblasts to localize efficiently at antigen injection sites in the pinna of the ear and peritoneal cavity. Failure of allogeneic lymphoblasts to extravasate in more than trace numbers into Listeria-antigen-induced exudates was reflected in an absence of other lymphocyte-mediated expressions of DTH. Thus, lymphocyte-dependent MCA was not detected in Listeria-antigen-induced peritoneal exudates borne by recipients of allogeneic immune TDL and blood monocytes were not recruited in increased numbers into such exudates as they were in exudates borne by syngeneic rats. But allogeneic restriction of the delayed inflammatory response to Listeria antigen was overcome, at least in part, when antigen-presenting macrophages of the same MHC type as the immune TDL donors were implanted in the peritoneal cavity. The results encourage the belief that the observed failure of immune TDL to transfer DTH to allogeneic recipients is related to the inability of sensitized donor T cells to recognize antigen displayed by allogeneic macrophages.     

Suppression of delayed-type hypersensitivity to syngeneic testicular cells in mice: involvement of suppressor T cells which act at the induction stage

Suppressor cells for delayed footpad reaction (DFR) against syngeneic testicular cells (TC) were detected in the spleen cells of donor mice immunized intravenously (iv) with viable syngeneic TC. Cyclophosphamide (CY)-pretreated recipients were given spleen cells from donors iv, immunized subcutaneously (sc) with syngeneic TC, and the footpad reaction at 24 hr was elicited with syngeneic TC 6 days after immunization. DFR in the recipients was suppressed by the transfer of spleen suppressor cells. The suppressor cells induced were Thy-1+, CY-sensitive, adult thymectomy (ATx)-resistant and act only at the induction stage. They directly suppress the generation of effector T cells for delayed-type hypersensitivity (DTH). When mice pretreated with CY were actively immunized with syngeneic TC, DFR could be provoked to a measurable level only when they were immunized sc. However, peritoneal exudate cells of those tolerant mice immunized sc without CY pretreatment or immunized iv with CY pretreatment also passively transferred DFR locally, suggesting the existence of effector T cells for DTH even in tolerant mice.     

T-T cell interaction in the induction of delayed-type hypersensitivity (DTH) responses: vaccinia virus-reactive helper T cell activity involved in enhanced in vivo induction of DTH responses and its application to augmentation of tumor-specific DTH responses

The role of antigen-specific helper T cells in augmenting the in vivo development of delayed-type hypersensitivity (DTH) responses was investigated. C3H/HeN mice were inoculated i.p. with vaccinia virus to generate virus-reactive helper T cell activity. These vaccinia virus-primed or unprimed mice were subsequently immunized subcutaneously (s.c.) with either trinitrophenyl (TNP)-modified syngeneic spleen cells (TNP-self), vaccinia virus-infected spleen cells (virus-self), or cells modified with TNP subsequent to virus infection (virus-self-TNP). Seven days later, these mice were tested for anti-TNP DTH responses either by challenging them directly with TNP-self into footpads or by utilizing a local adoptive transfer system. The results demonstrated that vaccinia virus-primed mice failed to generate significant anti-TNP DTH responses when s.c. immunization was provided by either virus-self or TNP-self alone. In contrast, vaccinia virus-primed mice, but not unprimed mice, could generate augmented anti-TNP DTH responses when immunized with virus-self-TNP. Anti-vaccinia virus-reactive helper activity was successfully transferred into 600 R x-irradiated unprimed syngeneic mice by injecting i.v. spleen cells from virus-primed mice. These helper T cells were found to be antigen specific and were mediated by Thy-1+, Lyt-1+2- cells. DTH effector cells enhanced by helper T cells were also antigen specific and were of the Thy-1+, Lyt-1+2- phenotype. Furthermore, vaccinia virus-reactive helper T cell activity could be applied to augment the induction of tumor-specific DTH responses by immunization with vaccinia virus-infected syngeneic X5563 tumor cells. T-T cell interaction between Lyt-1+ helper T cells and Lyt-1+ DTH effector T cells is discussed in the light of the augmenting mechanism of in vivo anti-tumor-specific immune responses.     

Induction of suppressor cells by a tumor-derived suppressor factor

Murine fibrosarcomas produce a factor that activates suppressor cells to inhibit expression of delayed-type hypersensitivity (DTH) responses to dinitrochlorobenzene (DNCB). This tumor-derived suppressor factor (TDSF) was partially purified by preparative isoelectric focusing of spent medium and 3 M KCl extracts of cultured methylcholanthrene-induced and spontaneous fibrosarcomas of C3H/He mice. Incubation of 1 micrograms/ml of a fraction, isoelectric pH less than 2.9, with normal syngeneic spleen cells for 1-6 hr at 37 degrees C induced suppressor cells that inhibited the primary DTH response to DNCB upon intraperitoneal transfer to normal C3H/HeJ mice. TDSF was not present in extracts of either syngeneic embryonic fibroblasts or normal spleen cells or in medium conditioned by normal peritoneal exudate cells but was present in 3 M KCl extracts of and the spent medium from four different cultured murine fibrosarcomas. TDSF activity was not restricted at the major histocompatibility complex. The suppressor cells inhibited the efferent limb of the DTH response because (1) hyporesponsive recipients of TDSF-treated spleen cells had splenic effector T cells capable of transferring DTH to DNCB into naive secondary recipients and (2) the ability of Lyt 1+,2- effector Tdth cells to transfer a secondary DTH response to DNCB was inhibited by co-incubation with macrophages or Lyt 1-,2+ T cells treated with TDSF. Preliminary biochemical analysis suggested that TDSF was an RNA- protein complex. Thus, several murine fibrosarcomas produced a soluble factor that activated splenic suppressor cells to depress the immune response to nonneoplastic antigens. These suppressor factors represent a novel group of regulatory molecules which may be ribonucleoprotein complexes.     

Regulation of the intensity of delayed-type hypersensitivity to sheep erythrocytes by the K-region of the major histocompatibility complex in mice

The injection of 6 x 10(9) sheep red blood cells (SRBC) to mice suppressed the delayed type hypersensitivity (DTH) in situ and activated spleen T cells which prevent sensitization of syngeneic recipients. Similar effect was obtained when suppressor cells induced in F1 hybrids were transferred to parental mice. Suppression was also reached in allogeneic strain combination if suppressor cells of donors and recipients shared the major histocompatibility complex (MHC). Studied performed with recombinant and mutant strains revealed that the prerequisite for interaction of DTH suppressors and effectors was the identity of K-region of MHC. Passive transfer of DTH to SRBC was also possible if donors and recipients were identical in K-region of MHC. It is believed that interaction between DTH suppressors and effectors is restricted by a region of MHC whose product takes part in antigen representation.     

Two types of murine helper T cell clone. II. Delayed-type hypersensitivity is mediated by TH1 clones

We have previously shown that at least two types of Lyt-1+, Lyt-2-, L3T4+ helper T cell clones can be distinguished in vitro by different patterns of lymphokine secretion and by different forms of B cell help. Evidence is presented here to show that one type of helper T cell clone (TH1) causes delayed-type hypersensitivity (DTH) when injected with the appropriate antigen into the footpads of naive mice. The antigen-specific, major histocompatability complex (MHC)-restricted footpad swelling reaction peaked at approximately 24 hr. Footpad swelling was induced by all TH1 clones tested so far, including clones specific for soluble, particulate, or allogeneic antigens. In contrast, local transfer of TH2 cells and antigen did not produce a DTH reaction, even when supplemented with syngeneic spleen accessory cells. Similarly, local transfer of an alloreactive cytotoxic T lymphocyte clone into appropriate recipients did not produce DTH. The requirements for the DTH reaction induced by TH1 cells were investigated further by using TH1 clones with dual specificity for both foreign antigens and M1s antigens. Although these clones responded in vitro to either antigen + syngeneic presenting cells, or M1s disparate spleen cells, they responded in vivo only to antigen + MHC and did not cause footpad swelling in an M1s-disparate mouse in the absence of antigen. Moreover, in vitro preactivation of TH1 or TH2 cells with the lectin concanavalin A was insufficient to induce DTH reactions upon subsequent injection into footpads. From these results, we conclude that the lack of DTH given by TH2 clones in vivo could be due to the inability of the TH2 cells to produce the correct mediators of DTH, or to a lack of stimulation of TH2 clones in the footpad environment.     

Studies on the transfer of protective immunity with lymphoid cells from mice immune to malaria sporozoites.

In an effort to understand the mechanisms involved in the protective immunity to malarial sporozoites, an A/J mouse/Plasmodium berghei model was studied. Protective immunity could consistently be adoptively transferred only by using sublethal irradiation of recipients (500 R); a spleen equivalent (100 X 10(6))of donor cells from immune syngeneic mice; and a small booster immunization (1 X 10(4)) of recipients with irradiation-attenuated sporozoites. Recipient animals treated in this manner were protected from lethal challenge with 1 X 10(4) nonattenuated sporozoites. Immune and nonimmune serum and spleen cells from nonimmune animals did not protect recipient mice. Fewer immune spleen cells (50 X 10(6)) protected some recipients. In vitro treatment of immune spleen cells with anti-theta sera and complement abolished their ability to transfer protection. This preliminary study suggests that protective sporozoite immunity can be transferred with cells, and that it is T cell dependent.     

Cellular cooperation in the expression of murine delayed-type hypersensitivity (DTH). 1. A normal accessory cell population enhances DTH produced by immune peritoneal exudate T lymphocytes

A murine system for local passive transfer of delayed-type hypersensitivity (DTH) has recently been described. It was determined that untreated and T-lymphocyte-enriched (nylon-wool-nonadherent) fractions of peritoneal exudate (PE) cells from immunized donors could be transferred with soluble antigen to normal recipient footpads to efficiently produce a local DTH response. Untreated spleen or lymph node (LN) cell populations were strikingly less capable in this regard. It is now reported that addition of normal untreated PE cell populations to immune T-enriched PE cells markedly enhanced the DTH response transferred by the latter. Specific swelling was dose dependent with respect to each cell type. Removal of T lymphocytes from the normal PE cell population did not affect its enhancement of DTH. By cotransfer of 1 X 10(7) normal PE cells, significant specific swelling was obtained using 1-3 X 10(5) T-enriched immune PE cells. This represented a three- to seven-fold reduction in the requirement for the latter cell type. This scheme of DTH enhancement was employed to evaluate the mechanisms for decreased capability of immune LN and spleen for DTH transfer when compared to PE. No evidence was found that either adherent or nonadherent suppressor cells are operative at the time of DTH expression. Cotransfer of a DTH-enhancing population failed to equalize DTH expression by LN and spleen with that of PE. It is concluded that DTH effector-T-cell activity is enriched in immune peritoneal exudate and that non-T-cell population(s) from that source actively enhance DTH expression.     

Phenomenon of parental resistance and its genetic regulation]

Lymphocytes of mice F1 (CBA X M523) and F1 (A X M523) transplanted to 1000 R irradiated CBA or A mice responded to the test antigens--SRBC or S. typhi Vi-antigen--by formation of 100--1000 times less antibody forming cells than in syngeneic recipients. An intermediate result is achieved when the lymphoid cells are transplanted to the irradiated M523 mice. Lymphocytes of mice F1 (A X CBA), F1 (CBA X C57Bl/6), or F1 (A X A.CA) developed a similar immune response in the irradiated syngeneic mice and in both parental lines. The ability of parental line M523 to respond to SRBC was the same as in the other lines studied when examined in situ or in adoptive transfer experiments. The stem hemopoietic cells of mice F1 (CBA X M523) develop in the spleen of CBA mice 2--2.5 times less hemopoietic colonies than in the spleen of syngeneic animals. A conclusion was drawn that mutation M523 in CBA mice inhibited the proliferation and differentiation of hemopoietic and lymphoid cells in the irradiated nonsyngeneic recipients.     

Immunoregulation of Heymann's nephritis. I. Induction of suppressor cells.

Pretreatment of Lewis rats with a series of injections of a renal tubular antigen (RTA) in IFA prevented induction of Heymann's nephritis (HN) when the rats were challenged with RTA in FCA. This absence of disease was confirmed by immunofluorescent staining for rat IgG and histologic examination of the kidneys as well as by lack of development of significant proteinuria. Passive transfer of spleen and lymph node cells from rats receiving such pretreatment into syngeneic recipients prevented induction of HN when these recipients were challenged with RTA in FCA. Passive transfer of serum obtained from pretreated rats was without effect. These results suggest that one of the mechanisms involved in preventing HN by this pretreatment regimen was the induction of suppressor cells. The results of spleen cell transformation indicated that the suppressor cells were specific for RTA as the immune response to a second antigen, PPD, was unaffected. When rats already had active early HN, the diseas course was unaffected by transfer of suppressor cells.     

Efficient natural defense mechanisms against Listeria monocytogenes in T and B cell-deficient allogeneic bone marrow radiation chimeras. Preactivated macrophages are the main effector cells in an early phase after bone marrow transfer

Radiation chimeras in the early phase after bone marrow transplantation are a good model to study the efficiency of the body's nonspecific defense system represented by macrophages (M phi), polymorphonuclear cells (PMN), and NK cells. These cell types are present in large numbers in spleen and liver at that time, whereas the specific immune system represented by T and B cells is functionally deficient. We previously reported enhanced activities in vitro of M phi (and PMN) from recipient animals in an early phase after allogeneic bone marrow transfer. We here demonstrate that these activities result in enhanced spontaneous resistance against Listeria monocytogenes in vivo: CFU of L. monocytogenes in spleen and liver 48 h after infection were about 1 or 2 to 4 log steps less than in untreated control mice of donor or host haplotype. This enhanced resistance decreased over the 4-mo period after marrow transfer. Preactivated M phi were identified as the most important effector cells. Isolated from spleen and peritoneal cavity, they performed enhanced killing of phagocytosed Listeria. Such preactivated M phi occurred in recipient animals after transfer of allogeneic but not of syngeneic bone marrow. The precise mechanism of M phi activation in the allogeneic radiation chimera in the complete absence of any detectable T cell function is not clear at present. However, these preactivated M phi display an important protective effect against L. monocytogenes: chimeras could eliminate Listeria without acquisition of positive delayed-type sensitivity when infected with 10(3) bacteria. An inoculum of 5 . 10(3) L. monocytogenes resulted either in prolonged survival compared with normal mice of the recipient haplotype or in definitive survival accompanied by a positive delayed-type sensitivity. We concluded that enhanced nonspecific immune functions can in part compensate for the defective specific immune system after bone marrow transfer.     

Regulatory action of immune B cells on delayed-type hypersensitivity in mice

Suppressor cells in delayed-type hypersensitivity (DTH) to soluble protein antigens were induced in vitro from BALB/c spleen cells. Transfer of these cells into syngeneic recipients resulted in suppression of the hosts' DTH responses in an antigen-specific manner. These suppressor cells were characterized as B cells by their adherence to nylon-wool columns, resistance to treatment of anti-Thy 1, -Ly 1, and -Ly 2 antibodies plus complement, adherence to anti-mouse immunoglobulin-coated dishes, and nonadherence to uncoated plastic dishes. In addition to being radiation sensitive, these suppressor B cells showed the capability of binding to the primed antigen. Thus, it was demonstrated that our in vitro-induced suppressor cells were antigen-specific B cells. When these suppressor B cells were transferred into the recipients, serum titers of specific antibodies were elevated and effector phase suppressor T cells were induced in the recipients. These results suggest that suppressor B cells exert their suppressor activity through the idiotype-anti-idiotype network.     

The inhibitory effect of T-2 toxin on tolerance induction of delayed-type hypersensitivity in mice.

Mice injected intravenously with 1 X 10(9) sheep red blood cells (SRBC) showed no delayed-type hypersensitivity (DTH) response to SRBC and were unresponsive to DTH induction by sc injection of an optimal dose of SRBC. However, when treated with T-2 toxin, a mycotoxin, 2 days after the iv injection, mice became to show significant DTH response and to be responsive to the DTH induction by the sc injection. When the spleen cells of the mice receiving the iv injection were transferred to unsensitized syngeneic recipients, the DTH response of the recipients to SRBC was suppressed. However, the suppressor activity of the spleen cells was decreased by T-2 toxin treatment. By the iv injection, cell population of the spleen was increased and that of the thymus decreased. In contrast, by T-2 toxin treatment 2 days after the iv injection, cell population of the spleen was not increased and that of the thymus was markedly decreased. The ratio of theta-bearing cells was increased in the spleen by the iv injection. However, such increase was not observed after the T-2 toxin treatment. The ratio of Ig-bearing cells in the spleen was not changed by the iv injection and the T-2 toxin treatment after the iv injection. T-2 toxin seems to interfere with generation of suppressor cells for the DTH response.     

Delayed-type hypersensitivity responses to H-Y: Characterization and mapping ofIr genes

This paper examines the delayed-type hypersensitivity (DTH) response to male (H-Y) antigen(s). Female mice of theH?2 ^b haplotype developed delayed footpad reaction to syngeneic or allogenic male thymus and spleen cells after priming with syngeneic male thymus and spleen cells. The reaction peaks at 24 h, has classical DTH histology and is specific to H-Y antigen as it is not elicited with female cells. Cell transfer studies show that donor/recipient matching at theI?B ^b subregion is necessary for sucessful transfer of DTH and that the effective primed population is Thy-1⁺, Lyt-1⁺, 2^?. DTH response to H-Y antigen appears to be confined to mice of theH?2 ^b haplotype. There appears to be a lack of associative recognition between H-Y antigen and MHC-coded determinants in the effector phase of DTH, and macrophage processing of H-Y seems likely, since nonresponder haplotypes can elicit the DTH response. Studies withH?2 ^b recombinant mouse strains indicate that the dominantIr gene is located in theI?B region. Female F₁ hybrid mice derived from matings of strains not involvingH?2 ^b haplotype failed to develop DTH to H-Y. In summary, these data imply that a complete correlation exists between DTH to H-Y and the ability to reject male skin graft, suggesting that the effector mechanisms of skin-graft rejection may closely involve DTH cells.     

Ongoing hapten-specific delayed-type hypersensitivity prevents generation of cytolytic T lymphocytes to the same hapten

Cytolytic T lymphocytes (CTL) specific for trinitrophenyl (TNP)-altered self antigens can be generated in vivo through the simultaneous injection of TNP-modified syngeneic spleen cells and H-2-compatible, minor histocompatibility locus (Mls)-disparate auxiliary spleen cells into the footpads of mice. The latter stimulates host helper cells to produce differentiative and proliferative signals required for the generation of CTL. Advent of this protocol allowed investigation of the initiation of two different cell-mediated immune responses, delayed-type hypersensitivity (DTH) and the generation of CTL, in the same experimental animal. Mice presensitized for CTL were able to develop DTH as well as normal controls. However, when mice were first sensitized for DTH, they were thereafter incapable of generating CTL. This effect was hapten specific, relatively long lasting, and preventable by treating mice with cyclophosphamide before sensitizing for DTH. Adoptive transfer of lymphoid cells from DTH-immune mice conferred DTH reactivity upon naive recipients but not a suppressed CTL response. Therefore, cells mediating DTH were not responsible for suppression of CTL. The mechanism for suppression has been discussed from the viewpoint of the suppressor-T-cell circuits that are known to be generated when animals are sensitized for DTH and which are susceptible to treatment with cyclophosphamide.     

Immunosuppression in experimental cryptococcosis in rats

Using a rat model, we have previously demonstrated that infection with Cryptococcus neoformans can trigger the production of a series of suppressor cells that specifically inhibit the cell-mediated immune response to a non-related antigen, human serum albumin (HSA), that has been injected 7 days after the infection. We previously determined that the cryptococcal infection induces afferent suppressor or suppressor induction cells (Ts₁) to HSA. The primary objective of the present study was to investigate the suppressor cells involved in the efferent phase of delayed-type hypersensitivity (DTH) response to HSA in rats infected with C. neoformans and immunized with the non-related antigen and determine the role that the Ts₁ cell plays in the induction of that cell. For this purpose, the spleen mononuclear (SpM) cells containing the Ts₁ or SpM cells from immunized non-infected rats (used as donor controls) were transferred to two groups of syngeneic naive recipients (first recipients). Later, the SpM cells from both groups of animals were transferred to rats immunized with HSA (second recipients). The efferent limb of the DTH response to HSA was suppressed in the recipients that received SpM cells from donors injected with Ts₁ cells. Additional HSA antigen was not required for induction of these efferent suppressor cells. Furthermore, we here show that these cells are resistant to treatment with cyclophosphamide (Cy), and that they can activate another suppressor population. The latter are Cy sensitive and are present in the immune recipient.     

Genetic restriction of delayed-type hypersensitivity to tuberculin in mice

An adoptive local transfer method has been used to study the immunological features and genetic restriction of cell interaction during the development of the delayed-type hypersensitivity (DTH) to tuberculin in mice. Peritoneal cells from the BCG-infected mice transfer the DTH to intact animals (into hind footpad) in both syngeneic and allogeneic donor-recipient combinations. Nonadherent cells (macrophage-deleted) transfer the reaction in syngeneic but not allogeneic combination. The use of H-2 recombinant mouse strains demonstrated that successful transfer of the DTH requires I-A subregion compatibility. Treatment of CBA cells with anti-Thy-1.2 antiserum abrogates the reaction transfer. These results indicate that antigen presentation to immune T-cells proliferating during DTH to tuberculin is mediated through the molecular products of the I-A subregion.     

Effects of pertussis toxin on delayed-type hypersensitivity responses and on the activity of suppressor T cells on the responses

Experiments were performed on mice to investigate the effects of pertussis toxin (PT) on delayed-type hypersensitivity (DTH) to ovalbumin (OA) and on the activity of suppressor T cells on the DTH (DTH-Ts). Mice immunized with alum-precipitated ovalbumin showed a transient DTH, which was determined as footpad swelling which disappeared 2 weeks after immunization. Maximal footpad swelling was observed 24 hr after DTH elicitation. On the other hand, when mice received PT (2 micrograms/mouse) at the time of immunization, the transient DTH became an enhanced and persistent DTH, which persisted for at least 4 weeks. In addition, the time of maximum footpad swelling was delayed from 24 to 48 hr after DTH elicitation. The immune spleen T cells from PT-treated mice showed a persistently high ability to transfer DTH into syngenic naive mice. DTH-Ts was induced in spleens of mice injected iv with OA-coupled syngeneic spleen cells. However, when these mice received PT at the time of suppressor induction, their spleen cells revealed considerably reduced suppressor activity. The activity of DTH-Ts was also reduced when DTH-Ts were either treated in vitro with PT or transferred into PT-injected recipient mice. From these results, interference with the suppressor function of DTH-Ts from PT was considered to be, at least in part, as an enhancing mechanism of DTH.     

A requirement for helper T cells in the induction of delayed-type hypersensitivity

This paper describes a model system for studying the role of helper T cells in the induction of delayed-type hypersensitivity (DTH). Cyclophosphamide- (CP) treated mice sensitized with antigen 3 days later develop high levels of delayed-type immunity; however, DTH cannot be demonstrated in mice that are sensitized with antigen 1 day after drug treatment. The inability to respond to antigen 1 day after CP treatment can be restored if either normal or low-dose primed spleen cells are transferred at the time of sensitization. Although irradiated (1500 rad) normal spleen cells are unable to restore DTH, such treatment has no effect on the primed spleen cell population. The lymphocytes responsible for restoring the DTH response were identified as T cells, in that treatment with anti-Thy-1.2 serum and C abrogated their effect. Furthermore, restoration of the DTH response was dependent on the presence of antigen at the time of lymphocyte transfer; irradiated primed cells could not transfer DTH alone. The DTH effector cells in reconstituted mice were identified as originating from the host and not from the transferred cell population. This was accomplished by using anti-H-2 serum to identify the source of the DTH effector cells after transferring parental (H-2b) irradiated primed spleen cells into CP-treated F1 mice (H-2b,k). Thus, the irradiated transferred cells are behaving as helper T cells and promoting the development of DTH effector cells in the host.     

Genetic restrictions of transfer of delayed-type hypersensitivity to sheep erythrocytes: local versus systemic transfer.

Regulation of the transfer of delayed-type hypersensitivity (DTH) reactions to SRBC was studied using two assays. In the systemic transfer, SRBC immune cells were transferred intravenously and the recipient challenged by injecting antigen into the footpad. In the local transfer assay, SRBC immune cells were mixed with antigen before transfer into the footpad of the recipient. These studies utilized B10.D2 and B10.BR mice which are congenic strains differing only at H-2 region. DTH reactions can be transferred across H-2 barriers using a local transfer assay. When the immune cells were transferred intravenously or depleted of adherent cells prior to local transfer, DTH reactions cannot be transferred to an H-2 congenic recipient. Spleen cells from naive mice syngeneic to the intravenously transferred cells supply the necessary accessory cell when mixed with the antigen prior to injection into the footpad. This accessory cell may be a macrophage.