Immune Response against Hamster Erythrocytes in the Low-Responder Mouse Strains

1) A subcutaneous injection of hamster erythrocytes (HRBC) in Freund's complete adjuvant (FCA) or an intravenous injection of hamster lymph node (HLN) cells suppressed antibody production against HRBC in the low-responder C57BL/6 and AKR mice, when HRBC in saline were given on the same day; 2) The suppressing effect of such treatments was neither detectable in the high-responder SL mice, nor in the C57BL/6 mice, which had been pre-sensitized with HRBC in FCA or hamster lymphoma cells; 3) Positive reactions of the peritoneal macrophage disappearance test and the enhanced antibody production were detected seven days after treatment with HRBC in FCA and HRBC in saline, or HLN cells and HRBC in saline; 4) The suppressing effect of such simultaneous treatments on anti-HRBC antibody production was eliminated by a transfer of normal syngeneic thymus cells to AKR mice or a transfer of thymus cells from SL to C57BL/6 mice. Suppression of the antibody production in the low-responder mice by the described simultaneous treatments may be due to a competitive involvement of HRBC-specific thymus-derived cells (T cells) in the developmental stages of delayed hypersensitivity and antibody production. High-responder SL mice appear to have enough T cells for development of the delayed hypersensitivity and as helper cells in antibody production. These results appear to support the concept that T cells for delayed hypersensitivity and antibody production to HRBC antigen are derived from the same original pool.     

Immune Response against Hamster Erythrocytes in the Low-Responder Mouse Strains

It was confirmed by passive transfer experiments that the function of thymus-derived cells specific for hamster erythrocytes (HRBC) was deficient in the low-responder mouse strains. 1) Antibody production against HRBC was enhanced by passive transfer of thymus cells from normal SL mice (high-responder) to normal C57BL/6 mice (low-responder). 2) The enhancing effect of passive transfer of thymus cells from SL mice was abrogated by pre-sensitization of the recipients (C57BL/6) with thymus cells from SL mice. 3) In C57BL/6 mice, antibody production against HRBC was enhanced by the transfer of lymph node or spleen cells from C57BL/6 mice which had been sensitized with HRBC in Freund's complete adjuvant or hamster lymphoma cells.     

Immune Response against Hamster Erythrocytes in the Low-Responder Mouse Strains

The production of anti-hapten antibody after immunization with trinitrophenylated (TNP) hamster erythrocytes (HRBC) or sheep erythrocytes (SRBC) was determined in high- and low-responder mouse strains against HRBC antigen. 1) Anti-TNP antibody was detected in sera of high-responder DDD and CF1 mice after primary immunization with TNP-HRBC, but not in those of low-responder C57BL/6 mice. 2) Anti-TNP antibody was detectable in sera of all the strains after primary immunization with TNP-SRBC. 3) Production of anti-TNP antibody was elicited after a booster injection of TNP-HRBC in low-responder C57BL/6 mice pre-sensitized with HRBC in Freund's complete adjuvant. These results suggest that functions of thymus-derived cells specific for HRBC antigen are deficient in low-responder mice.     

Immune Response against Hamster Erythrocytes in the Low-Responder Mouse Strains

C57BL/6 and AKR mice were treated with hamster erythrocytes (HRBC) in complete Freund's adjuvant (CFA) or incomplete Freund's adjuvant (IFA) and the development of delayed hypersensitivity and antibody production were examined. 1) Delayed hypersensitivity against HRBC antigen, as determined by the peritoneal macrophage disappearance test, was detected in mice sensitized with HRBC in CFA but not in those sensitized with HRBC in IFA. 2) Antibody production against HRBC or hapten TNP after a booster injection of HRBC or trinitrophenylated HRBC (TNP-HRBC) in saline was enhanced by pretreatment with HRBC in CFA or IFA. 3) Delayed hypersensitivity was not detectable after a booster sensitization with HRBC in CFA in mice which had been pretreated with HRBC in IFA 2 weeks earlier. In the mice treated with both HRBC in IFA (day ?21) and in CFA (day ?7), however, an enhanced antibody production against HRBC or TNP was detected after an intravenous injection with HRBC or TNP-HRBC in saline (day 0). These results suggest that sensitized effector lymphocytes in delayed hypersensitivity and helper cells in antibody production may be derived from the same pool of unprimed T cells. The pool of unprimed T cells with a capacity to differentiate into either type of primed T cells may be exhausted after pretreatment with the antigen in IFA, and the primed helper T cells may not be able to differentiate into sensitized lymphocytes even after sensitization with the antigen in CFA, which favors development of delayed hypersensitivity in normal controls.     

Immune Response against Hamster Erythrocytes in the Low-Responder Mouse Strains

Antibody response against hamster red blood cells (H-RBC) was examined in inbred strains of C57BL/6, AKR, C3H/He, DDD and SL mice, and outbred CF1 mice. 1) There were strain differences in antibody response after a primary intravenous injection of H-RBC. DDD, SL and CF1 mice belonged to high-responder strains, while C57BL/6, AKR and C3H/He to low-responder strains. In the spleens of immunized CF1 and SL, 40 to 70 times as many plaque-forming cells (PFC) as those in C57BL/6 mice were detected. The magnitudes of the response were: CF1 ≒ SL>DDD>>C3H/He ? AKR>C57BL/6. 2) 2-mercaptoethanol resistant (MER) antibody was detected in neither low- nor high-responders after a primary intravenous antigen-injection. 3) After a secondary intravenous antigen-injection, MER antibody was detected in all the SL mice, but only in 30 to 50% of AKR and C57BL/6 mice. 4) A subcutaneous injection of H-RBC in Freund's complete adjuvant (FCA) did not elicit antibody production within 10 days. When mice pre-sensitized 7 days in advance w^Tith H-RBC in FCA were intravenously injected with H-RBC, enhanced antibody production of the primary type was observed in all the mouse strains. 5) In pre-sensitized mice, the extent of the enhancement of antibody production was the highest in low-responder C57BL/6 mice and the lowest in high-responder SL and CF1 strains. Thus, there was no strain difference in antibody titers or the numbers of PFC after the booster.     

Immune Response against Hamster Erythrocytes in the Low-Responder Mouse Strains

In a previous paper we reported that an inbred strain of SL mice and an outbred strain of CF1 mice belonged to the high-responder strains in antibody production after primary immunization with hamster erythrocytes (H-RBC), while inbred strains of C57BL/6, AKR and C3H/He mice belonged to low-responder strains. In the present study we obtained the following results. 1) Pre-sensitization with hamster lymphoma enhanced antibody production after an intravenous injection of H-RBC. There was no strain difference in the pattern of antibody production against H-RBC among pre-sensitized mice. 2) The pattern of enhanced antibody production after an intravenous injection of H-RBC into pre-sensitized mice assumed the primary type in terms of time of appearance of hemolysin plaque-forming cells (PFC) in the spleens and the conversion from 2-mercaptoethanol sensitive to 2-mercaptoethanol resistant antibody production, when the intervals between both treatments were within 7 days. 3) Pre-sensitization with lymphoma induced not only an increase in numbers of PFC after an intravenous injection of H-RBC, but also an increase in the size of the hemolysin plaques. These results suggested that sensitization with hamster lymphoma stimulated some kinds of immuno-competent cells, which could contribute to antibody production against H-RBC after a booster injection of H-RBC.     

Immune Response against Hamster Erythrocytes in the Low-Responder Mouse Strains

Patterns of proliferation of antibody-forming cells after an intravenous immunization with hamster erythrocytes (HRBC) were compared in groups of mice possessing different activities of thymus-derived lymphocytes (T cells). 1) Marked differences in the numbers of hemolysin plaque-forming cells (PFC) after HRBC injection were found among the low- and high-responder normal mice and those pretreated with HRBC in complete Freund's adjuvant (CFA) or incomplete adjuvant (IFA), and they appeared to depend primarily upon the different rates of proliferation of antibody-forming cells rather than on the numbers of antigen-specific lymphocytes initiating the antibody response. 2) The numbers of hemolytic foci were slightly larger in mice with large numbers of PFC (normal SL mice, the pretreated SL and C57BL/6 mice) than in those with small numbers of PFC (normal C57BL/6 mice). The numbers of hemolytic foci increased at almost the same rate from day 2 to day 3 in both groups, while the numbers of PFC increased more efficiently in mice with large numbers of PFC than in those with small numbers of PFC from day 2 to day 3. Individual hemolytic foci appeared to contain larger numbers of PFC in mice with large total numbers of PFC than in those with small total numbers of PFC. 3) The numbers of rosette-forming cells (RFC) were increased by pretreatment with HRBC in CFA and by pretreatment with HRBC in IFA to almost the same extent. Rates of increases in PFC were, however, larger by pretreatment with HRBC in CFA than with HRBC in IFA. These results suggested that the activity of the T cell determined not only the rates of proliferation of antibody-forming cells but also the antibody-producing capacity of each cell.     

Immune response against hamster erythrocytes in the low-responder mouse strains. XI. Strain difference in the effects of various microbial adjuvants.

Enhancing and suppressing effects of microbial adjuvants were studied in female mice of the C3H/He, AKR and SL strains. Propionibacterium acnes, Bordetella pertussis, BCG and yeast cell wall (YCW) were chosen as adjuvants. As antigens, we chose hamster erythrocytes (HRBC) which proved to be a weak antigen for mice. Adjuvants were given on day --7, day 0 or day 3, and HRBC were injected on day 0. The results were as follows. 1) P. acnes facilitated IgM and IgG antibody production in AKR mice and suppressed IgM antibody production in SL mice, when given on day --7. When P. acnes was given on day 0, they suppressed IgM antibody production in all of the strains used. 2) When B. pertussis was given on day 0, it exhibited enhancing effects on IgG antibody production in all of the strains and a suppressing effect on IgM antibody production in SL mice. 3) BCG suppressed IgM antibody production in all strains when given on day 0. 4) YCW showed no influence on antibody production in any combination used in this work. 5) SL mice were very sensitive to suppressing effects by adjuvants. Strain differences in the expression of enhancing and suppressing effects by adjuvants appear to be under some control independent of antigen-specific immune response genes.     

Immune Response against Hamster Erythrocytes in the Low-Responder Mouse Strains

Enhancing and suppressing effects of microbial adjuvants were studied in female mice of the C3H/He, AKR and SL strains. Propionibacterium acnes, Bordetella pertussis, BCG and yeast cell wall (YCW) were chosen as adjuvants. As antigens, we chose hamster erythrocytes (HRBC) which proved to be a weak antigen for mice. Adjuvants were given on day —7, day 0 or day 3, and HRBC were injected on day 0. The results were as follows. 1) P. acnes facilitated IgM and IgG antibody production in AKR mice and suppressed IgM antibody production in SL mice, when given on day —7. When P. acnes was given on day 0, they suppressed IgM antibody production in all of the strains used. 2) When B. pertussis was given on day 0, it exhibited enhancing effects on IgG antibody production in all of the strains and a suppressing effect on IgM antibody production in SL mice. 3) BCG suppressed IgM antibody production in all strains when given on day 0. 4) YCW showed no influence on antibody production in any combination used in this work. 5) SL mice were very sensitive to suppressing effects by adjuvants. Strain differences in the expression of enhancing and suppressing effects by adjuvants appear to be under some control independent of antigen-specific immune response genes.     

Induction of allograft tolerance to the H-Y antigen in adult C57BL/6 mice: differential effects on delayed-type hypersensitivity and cytolytic T-lymphocyte activity

This study describes the induction of allograft tolerance to the "male-specific," minor histocompatibility antigen, H-Y, in adult C57BL/6 female mice, and the effects of this tolerance induction on two immune parameters associated with graft rejection: delayed-type hypersensitivity (DTH) and cytolytic T-lymphocytes (CTL). B6 females tolerized to H-Y, by a single iv injection of C57BL/6 male lymphocytes, exhibited prolonged or permanent survival of B6 male tail skin grafts. Graft-induced DTH against H-Y antigen was reduced or abrogated in tolerized females. Delayed onset of graft rejection in partially tolerant females correlated with delayed onset of DTH, and eventual rejection of grafts was accompanied by an increase in H-Y-specific DTH. In contrast, H-Y-specific CTL activity was not consistent with graft status. These data demonstrate a correlation between H-Y-specific DTH and rejection of male skin grafts by B6 female mice and are most consistent with a major effector role for DTH in chronic graft rejection.     

Defective vaccine-induced immunity to Schistosoma mansoni in P strain mice. II. Analysis of cellular responses

Cellular immune responses against larval and adult schistosome antigens were studied in attenuated cercariae-vaccinated P and C57BL/6 mice to define differences correlating with the inability of P mice to develop vaccine-induced resistance to challenge Schistosoma mansoni infection. Vaccinated P mice failed to demonstrate delayed hypersensitivity upon skin-testing with soluble worm antigens, whereas mice of the highly resistant strain C57BL/6 developed a significant 24-hr response to worm antigens in vivo. Also, when schistosome antigens were injected i.p., vaccinated P mice failed to exhibit an activated macrophage response in vivo, whereas vaccinated C57BL/6 mice developed macrophages with significant larvicidal and tumoricidal activity at the site of specific antigen challenge. Immune sera from either vaccinated C57BL/6 or P mice were equally effective at opsonizing the schistosomula targets in the larvicidal assay. In vitro analyses of cellular defects revealed that although T lymphocytes from vaccinated P mice showed blastogenic responses to schistosome antigens that were similar in magnitude and kinetics to those of cells from the C57BL/6 animals, T cells from C57BL/6 mice produced higher levels of macrophage-activating lymphokines (LK), including gamma-interferon. Macrophages from control C57BL/6 mice were also more responsive to activation by LK than macrophages from P mice were, as assessed by stimulation of these cells to kill skin-stage schistosomula in vitro. These two aspects of cellular dysfunction in P mice had the combined effect of rendering P macrophages incapable of activation by LK from mice of their own strain, whereas macrophages from C57BL/6 mice were strongly activated by LK from vaccinated C57BL/6 mice in the same assays. Thus, a correlation exists between T lymphocyte/macrophage dysfunction and lack of resistance to challenge infection in vaccinated P mice, which suggests that delayed hypersensitivity response plays a major role in the immunity to S. mansoni infection that is induced by exposure to radiation-attenuated cercariae.     

Immunological properties of Propionibacterium acnes. I. Potentiation and Suppression on antibody response to sheep and hamster erythrocytes in mice.

Adjuvant activity of phenol-treated cells of Propionibacterium acnes C-7 in antibody response was investigated in ICR mice. Simultaneous administration (day 0) of P. acnes (i.p.) and sheep red blood cells (SRBC) (i.v.) enhanced the formation of direct plaque-forming cells (PFC) on days 2, and the formation of indirect PFC response on day 7 and thereafter. Conversely, pretreatment from 11 to 14 days before antigen injection suppressed markedly the antibody response. The potentiation and the suppression of immune response depended on doses of antigen and of P. acnes, the timing of adjuvant injection and the time of assay. The two opposite phenomena caused by P. acnes were also confirmed in antibody response against hamster red blood cells (HRBC). Pretreatment with P. acnes 1 to 14 days before antigen injection suppressed markedly anti-HRBC antibody response, whereas P. acnes injected simultaneously with HRBC or one day after injection of the antigen induced prolongation of antibody response and the production of 2-mercaptoethanol-resistant antibody.     

Interrelations of cellular and humoral immune response and different doses of sheep erythrocytes in mice]

In experiments on CBA and C57BL/6 mice the generation of antibody-forming cells respectively either in the popliteal lymph nodes or spleen as well as a rate of delayed type hypersensitivity response (DTHR) on the background of subcutaneous (into foot) or intraperitoneal injection of different doses of sheep erythrocytes (from 10(4) to 10(8)) have been studied. In so doing two types of immune response can be isolated on the dependence upon the sensitivity threshold to antigen of DTHR and humoral immunity. Thus in C57BL/6 mice the antigen threshold for DTHR is of one time (in intraperitoneal immunization) or of a two times (in subcutaneous) lower order than for antibody response. In CBA line mice under subcutaneous immunization there can be seen quite an opposite picture while intraperitoneal immunization causes exact correlation of antigen threshold for cellular and humoral immune response.     

Anti-tumor vaccine adjuvant effects of IL-2 liposomes in mice immunized against MCA-102 sarcoma.

MCA-102, a murine sarcoma previously reported to be non-immunogenic in C57/BL6 murine tumor models was used in a tumor vaccine preparation which included liposome encapsulated IL-2 as an adjuvant. C57/BL6 mice were immunized in the right hind footpad with irradiated MCA-102 murine sarcoma cells on days 0, 7, and 21 with or without IL-2 liposome adjuvant at 25,000 IL-2 units/injection. Mice were challenged with live tumor in the right flank on day 35. Survival of mice given IL-2 liposomes with irradiated MCA-102 cells was significantly prolonged over mice given tumor antigen with saline, and non-immunized mice. In addition, mice which received the IL-2 liposome adjuvant also had prolonged survival over those mice immunized with the additional control adjuvants of free IL-2 or dimyristoyl phosphatidyl choline (DMPC) lipid in the form of empty liposomes. IL-2 liposome plus tumor antigen also yielded a significant local protective response against live MCA-102 tumor challenge. When live tumor was injected into the site of previous immunizations on day 21 after two immunizations, the IL-2 liposome adjuvant group showed significantly delayed local growth of tumor compared to animals immunized without adjuvant, or with the adjuvants of empty liposomes or free IL-2. Finally, immunized mice were challenged with irradiated tumor cells and saline intradermally in the ears and delayed type hypersensitivity (DTH), an indicator of helper T cell response, was measured.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of BCG (Bacillus Calmette-Guérin) vaccines on immune responses in mice. I. Possible effect of BCG on helper T cells.

The effects of killed and living BCG on antibody production against hamster erythrocytes (HRBC) and the 2, 4, 6-trinitrophenyl (TNP) group were studied in SL mice. Killed and living BCG, each in doses of 0.008 mg, 0.08 mg, 0.8 mg and 8 mg per mouse, were intravenously inoculated 7 days prior to primary immunization with HRBC. Secondary immunization was carried out 28 days later with TNP-HRBC. Anti-HRBC and anti-TNP antibodies were estimated by a hemagglutination test. The results showed that pretreatment with killed or living BCG enhanced the antibody production against both HRBC and TNP. Comparing the effects of these two BCG preparations, it was noted that killed BCG augmented the anti-HRBC antibody production more effectively than living BCG. In regard to the anti-TNP antibody production, living BCG exhibited a greater augmenting effect than killed BCG. This difference in the modes of action of killed and living BCG was remarkable when two groups given 8 mg of killed and living BCG were compared. In addition, it was shown that living BCG at a dose as high as 8 mg was able to augment the anti-TNP antibody production, even in the absence of preceding immunization with HRBC.     

Effects of BCG (Bacillus Calmette–Guérin) Vaccines on Immune Responses in Mice

The effects of killed and living BCG on antibody production against hamster erythrocytes (HRBC) and the 2, 4, 6-trinitrophenyl (TNP) group were studied in SL mice. Killed and living BCG, each in doses of 0.008 mg, 0.08 mg, 0.8 mg and 8 mg per mouse, were intravenously inoculated 7 days prior to primary immunization with HRBC. Secondary immunization was carried out 28 days later with TNP-HRBC. Anti-HRBC and anti-TNP antibodies were estimated by a hemagglutination test. The results showed that pretreatment with killed or living BCG enhanced the antibody production against both HRBC and TNP. Comparing the effects of these two BCG preparations, it was noted that killed BCG augmented the anti-HRBC antibody production more effectively than living BCG. In regard to the anti-TNP antibody production, living BCG exhibited a greater augmenting effect than killed BCG. This difference in the modes of action of killed and living BCG was remarkable when two groups given 8 mg of killed and living BCG were compared. In addition, it was shown that living BCG at a dose as high as 8 mg was able to augment the anti-TNP antibody production, even in the absence of preceding immunization with HRBC.     

Difference in antibody production to hererologus erythrocytes in conventional, specific-pathogen-free (SPF), germfree and antigen-free mice.

The expression of antibody-producing capacities against hamster erythrocytes (HRBC), known to be weakly immunogenic in mice, was compared among conventional, SPF, germfree and antigen-free mice. ICR strain germfree and antigen-free mice showed antibody production to HRBC comparable to that in conventional or specific-pathogen-free (SPF) mice. In the NC strain, some of the conventional mice produced low titers of antibody after a single injection of HRBC, but none of the germfree mice showed such a transient antibody production. In the ICR-KIG strain, which was selected from the colony-bred ICR strain, antibodies with high titers were produced after a single injection of HRBC under both conventional and germfree conditions. The onset of conversion from 2-mercaptoethanol (2-ME) sensitive to 2-ME resistant antibody after a single injection of HRBC was not delayed in the germfree mice when compared with the conventional or SPF mice. Antibody production to sheep erythrocytes (SRBC), known to be highly immunogenic in mice, was not influenced by exogeneous stimulation from microorganisms or diet. No differences in antibody production to SRBC were detected irrespective of the maintenance conditions of the mice. Stimulation with microorganisms or diet may not be required as essential elements for the maturation of antibody-producing capacities, but such a stimulation appears to modify the antibody response. The modifying effect was more prominent in the antibody response against weakly immunogenic antigens than against highly immunogenic ones.     

Induction of protective immunity against Schistosoma mansoni by a nonliving vaccine is dependent on the method of antigen presentation

A preparation of nonliving parasite antigens containing both soluble and particulate components of frozen-and-thawed invasive larvae was used to immunize C57BL/6J mice against challenge Schistosoma mansoni infection. The method of antigen presentation was observed to be critical to the ability of this preparation to induce protective immunity, because intradermal administration in conjunction with a bacterial adjuvant (BCG) resulted in strong protection against challenge parasites (51% reduction in worm burden in six experiments), whereas i.v. injection of the same antigenic preparation was completely ineffective. Induction of resistance was accompanied by specific immune responsiveness toward schistosome antigens. Protection correlated more closely with sensitization for specific delayed hypersensitivity than with elicitation of circulating antibodies to larval surface antigens or immediate hypersensitivity in these models. These results suggest that it will be possible to design a defined vaccine against S. mansoni infection, but that identification of the route of antigen presentation that most effectively elicits relevant immune effector mechanisms will be crucial to the success of any vaccination protocol involving nonliving antigens.     

IgE antibody responses against Japanese cedar pollen in the mouse

IgE antibody responses against Japanese cedar pollen in the mouse were investigated to develop a mouse model of human allergy for combinations of factors including pollen administration routes, elicitation antigens and inbred mouse strains. Daily short term inhalation of native pollen or intratracheal administration of pollen suspended in saline induced IgE antibody responses in DBA/2, BDF1 and Balb/c mice, but failed to induce any detectable responses in C57BL/6 and C57BL/10 mice. Intraperitoneal injection of pollen suspension also induced IgE antibody responses in DBA/2, BDF1 and Balb/c mice but not in C57BL/6 mice. IgE antibody responses against pollen described above were detected by passive cutaneous anaphylaxis (PCA) reactions using crude extract of pollen as an elicitation antigen. On the other hand, IgE antibodies specific for antigen Sugi basic protein (AgSBP), which is a major allergen of pollen in humans (Yasueda, H., Yui, Shimizu, T., and Shida, T., 1983. Isolation and partial characterization of the major allergen from Japanese cedar (Cryptomeria japonica) pollen. J. Allergy Clin. Immunol. 71: 77-86), were also detected by PCA reactions using AgSBP in the sera from mice which received secondary or the tertiary stimulation by pollen. These results suggest that IgE antibody responses against Japanese cedar pollen in the mouse can be induced by airway sensitization and that the responses are genetically controlled by H-2-linked immune response genes. The results also suggest that not only IgE antibody responses specific for components other than AgSBP but also responses specific for AgSBP can be induced in the mouse by repeating appropriate sensitization by pollen.     

Immune Response against Hamster Erythrocytes in the Low-Responder Mouse Strains

Golden hamsters were used as hosts in this work, and mice of various strains as donors of antigens. 1) There were no strain differences in immunogenicity of erythrocytes from C57BL/6, AKR, SL and CF1 mice. 2) Primary intravenous immunization with mouse erythrocytes (MRBC) induced the production of hemolysin plaque-forming cells (PFC) in a large number, but elicited only in a negligible titer production of 2-mercaptoethanol-resistant antibody. 3) 2-Mercaptoethanol-resistant antibody was produced more efficiently in hamsters pre-sensitized with mouse lymph node (MLN) cells rather than those pre-immunized with MRBC after a booster with MRBC. 4) Numbers of PFC in pre-sensitized hamsters were three-times that of the non-sensitized hamsters after a booster with MRBC, when pre-sensitization was performed intradermally with a small number of MLN cells. 5) Average diameter of the hemolysin plaques in pre-sensitized hamsters was one and a half times larger than that in non-sensitized hamsters. Conclusions agree well with the results in our previous papers that the reversed combination of hosts and antigen donors employed support the concept that certain processes required for delayed hypersensitivity contributed to antibody production under a condition suitable for antibody response.