C57BL/10/CR mice: nonresponders to activation by the lipid a moiety of bacterial lipopolysaccharide.

C57BL/10/CR mice do not respond to the lipid A moiety of LPS. This defect was demonstrated in vivo by a decreased production of the acute phase serum amyloid protein SAA. In addition, the defect was demonstrated in vitro by using cultures of spleen cells and peritoneal cells. No mitogenesis of spleen cells or enhanced glucose utilization by either spleen cells or peritoneal cells was observed when the cells were stimulated by lipid A or phenol-extracted Escherichia coli K235 LPS. The response of these mice to PHA, Con A, Poly I:C, 8BrcGMP, and butanol extraced E. coli K235 LPS was normal. Thus, the inability of lipid A to stimulate B lymphocyte mitogenesis and activate peritoneal cells in vitro may correlate with its inability to induce the acute phase SAA in vivo. B10/CR mice represent another strain, similar to the C3H/HeJ, which is nonresponsive to lipid A and should be useful in eludcidating the mechanism by which bacterial LPS activates cells.     

Sequential production of alpha and beta interferons and gamma interferon in the circulation of Listeria monocytogenes-infected mice after stimulation with bacterial lipopolysaccharide

Sequential production of interferon (IFN)-alpha/beta and IFN-gamma in the circulation of mice which had been previously infected with viable Listeria monocytogenes was induced by injection of lipopolysaccharide (LPS) derived from Salmonella typhimurium. IFN-alpha/beta production occurred 2 hr after injection of LPS, thereafter IFN-gamma appeared and the maximum titer was demonstrated at 6 hr. At that time, almost all of the IFN was IFN-gamma. IFN-gamma production in response to LPS was observed from the 5th through the 11th day after infection with Listeria, but it was not demonstrated in either mice infected with lower doses of viable Listeria or mice immunized with heat-killed bacteria. IFN-alpha/beta production was not drastically affected by treatment with hydrocortisone, cyclophosphamide, carrageenan, antithymocyte serum, or anti-asialo GM1 antibody, whereas IFN-gamma production was suppressed by administration of all those agents. Noteworthily, IFN-alpha/beta, but not IFN-gamma, was produced even 6 hr after stimulation with LPS in cyclophosphamide- or antithymocyte serum-treated mice. IFN-gamma induction by LPS was markedly suppressed in mice in which IFN-alpha/beta produced by Listeria infection itself had been depleted by treatment with anti-mouse IFN-alpha/beta antibody, but it was not inhibited in mice when IFN-alpha/beta induced not by Listeria infection but by LPS had been depleted by treatment with anti-mouse IFN-alpha/beta antibody.     

Cellular mechanism of endotoxin unresponsiveness in C3H/HeJ mice.

B cells from C3H/HeJ mice fail to respond to an endotoxin (LPS K235) which is mitogenic for normal mice including the closely related C3H/HeN strain. The cellular basis for this unresponsive state has been investigated. The C3H/HeJ mice have normal numbers of B cells, which are capable of normal responses to other B cell mitogens, such as polyinosinic acid (Poly I). Addition of normal macrophages or spleen cells fails to reconstitute the normal response. Furthermore, neither macrophages nor spleen cells from the C3H/HeJ strain suppress the normal C3H/HeN spleen cells. Finally, spleen cells enriched for B cells by the removal of macrophages or T cells demonstrate the same differences in responsiveness to LPS. These results indicate that LPS unresponsiveness is a defect of the B cell itself and not due to suppressor cells or the absence of helper cells. When LPS is added to Poly I-stimulated cultures, there is additional enhancement of the response of normal C3H/HeN spleen cells. However, LPS causes a dose-dependent suppression of the Poly I response of C3H/HeJ spleen cells. This suppression is dependent on the time of addition of LPS to the Poly I-stimulated cultures. These data are interpreted as indicating that the binding of LPS to the membrane of C3H/HeJ B cells results in their inactivation or suppression, and that this is the basis of LPS unresponsiveness in this mouse strain.     

The effect of lipopolysaccharide desensitization on the regulation of in vivo induction of immunologic tolerance and antibody production and in vitro release of IL-1

As previously reported, LPS and 8-derivatized guanosine (both generators of IL-1 release), as well as IL-1 itself interfere with the in vivo induction of tolerance to DHGG in A/J mice. In the present studies it was demonstrated that desensitization of either A/J or CBA/CaJ mice with LPS aborts the ability of LPS to interfere with the induction of tolerance to DHGG. The abrogation of the ability of LPS to interfere with tolerance by LPS desensitization is not the result of neutralization of LPS by antibody produced to LPS during desensitization. Desensitization with LPS also aborts the interference with tolerance induction by 7-methyl-8-oxoguanosine. LPS desensitization inhibits the ability of LPS and/or 7-methyl-8-oxoguanosine to both convert a tolerogenic signal to an immunogenic signal and interfere with the induction of a tolerant state to a subsequent injection of Ag. The effects resulting from desensitization may be in part attributed to the depletion of IL-1. LPS desensitization also modulates the antibody response to injection of the AG, AHGG. Desensitization with LPS markedly suppresses the antibody response to a subsequent injection of AHGG in CBA/CaJ mice. Desensitization with LPS also inhibits the anti-HGG antibody response in A/J mice, but in this strain its effect is dependent on the route of injection of AHGG. In an experiment directly comparing the responses of normal and desensitized A/J mice to either intravenous or intraperitoneal injection of AHGG, desensitization only suppressed the response in mice injected with AHGG i.p.. Desensitization with LPS also inhibits the ability of LPS to act as an adjuvant in a subsequent antibody response to AHGG. Not only does desensitization interfere with the primary antibody response to AHGG, but it also interferes with the secondary response, suggesting that the primary injection after desensitization induces a state of immunologic tolerance.     

Regulation of MHC expression in vivo. Bacterial lipopolysaccharide induces class I and II MHC products in mouse tissues by a T cell-independent, cyclosporine-sensitive mechanism

The effect of injections of bacterial LPS on the expression of class I and II products of the MHC in mouse tissues was investigated. MHC products were assessed in tissue homogenates by radiolabeled antibody binding and in tissue sections by indirect immunoperoxidase (IIP) staining. In mice given two i.p. injections of LPS from Escherichia coli or Salmonella minnesota, there were increases in class I and II MHC products in kidney, liver, heart, lung, and pancreas. Focusing on the changes in kidney, we demonstrated that the increase in MHC expression occurred in tubules and, in the case of class I, in glomeruli. LPS treatment also increased the deposition of Ig in glomeruli. Expressed on a standard curve, the total kidney class I and II expression was elevated approximately 10-fold. Time course studies indicated that increased class I expression could be induced by a single LPS injection, whereas class II induction required a second injection. The induction was influenced by the LPS sensitivity of the mice, being much greater in LPS-sensitive C3H/HeSn mice than in LPS-resistant C3H/HeJ mice. LPS induced class I and II Ag in nude mice and in mice with severe combined immunodeficiency, indicating that T cells were not required. Nevertheless, the effect of LPS was inhibitable by cyclosporine and by a mAb against IFN-gamma indicating that IFN-gamma was required for the MHC induction. We conclude that LPS induces an increase in expression and a redistribution of MHC products in kidney and in other tissues by a T cell-independent, cyclosporine-sensitive pathway. These findings are probably related to the known ability of LPS to mediate release of IFN-gamma and other cytokines.     

Immunosuppression of normal lymphoid cells by serum from mice undergoing chronic graft-vs-host disease.

Spleen cells from F1 mice undergoing chronic graft-vs-host (GVH) reaction, induced by injection of parental cells, were shown to be immunosuppressed since their in vitro responses to the mitogens concanavalin A (Con A) and bacterial lipopolysaccharide (LPS) were substantially lower than control animals. Serum, from mice undergoing GVH, when cultured in vitro with normal spleen cells was immunosuppressive. The proliferation response to Con A and allogeneic cells of normal syngeneic, allogeneic, and parental spleen cells was 90% suppressed when serum from mice undergoing chronic GVH was added in comparison to the addition of serum from untreated F1 mice. Similarly, the in vitro antibody response to a T-dependent antigen was impaired; however, the antibody response to a T-independent antigen was not impaired. These results indicate that T cell functions are more sensitive than are B cell functions to immunosuppressive factors in the serum of mice undergoing GVH.     

Nonspecific Elicitation of Antibody-Forming Cells in the Mouse Spleen by Bacterial Lipopolysaccharide

Mechanisms of nonspecific elicitation of anti-sheep erythrocyte (SRBC) hemolytic antibody plaque-forming cells (PFC) in mouse spleens with an injection of bacterial endotoxin (lipopolysaccharide (LPS)) were studied in comparison with the genesis of naturally occurring ‘background’ PFC in normal mouse spleens and of rapidly arising PFC in mouse spleens after immunization with SRBC. The cytokinetic pattern of anti-SRBC PFC response after an injection of LPS was quite different from that of the response elicited after immunization with SRBC. In addition, even though LPS nonspecifically elicited anti-SRBC PFC response in mice, LPS could not confer any immunological memory on mouse immunocytes for a ‘secondary-type’ anti-SRBC PFC response to restimulation with LPS or SRBC. The administration of rabbit anti-mouse thymocyte immunoglobulin or anti-SRBC antiserum in mice markedly suppressed the PFC response after immunization with SRBC, but did not do so after stimulation with LPS. Neonatally thymectomized mice could still respond to stimulation with LPS, producing anti-SRBC PFC in their spleens. Injections of actinomycin D or cyclophosphamide into mice resulted in obvious reductions of the PFC responses elicited by either LPS or SRBC. However, injections of these immunosuppressive antisera or drugs did not affect the number of anti-SRBC PFC in normal mouse spleens. These results suggest that the geneses of anti-SRBC PFC developed under different conditions, i.e., background PFC, LPS-stimulated PFC, and antigen-stimulated PFC, are quite different from each other, and that the nonspecific elicitation of anti-SRBC PFC by LPS does not require the helper function of T lymphocytes. No obvious difference, however, was observed in the time of ontogenic maturation among these three different anti-SRBC PFC in the mouse spleens judging from when they were first manifested after birth.     

Strain Differences in the Immunogenicity of Aggregated Human IgG and the Adjuvant Action of Lipopolysaccharide on the Low-Responder Strain of Mice

Strain differences in the antibody response to human IgG (HGG) were observed when aggregated HGG was injected intravenously. Lipopolysaccharide (LPS) administered subsequently markedly enhanced the antibody response to HGG in low responder C57BL/6 mice as compared with that in high responder DDD, C3H/He or (C57BL/6 × DDD)F₁ mice. Aggregate-free preparation of HGG at a dose of 0.5 mg induced immunological tolerance in all strains of mice tested. LPS injected subsequently converted tolerogenic, aggregate-free HGG into immunogen in DDD mice but not in C57BL/6 mice. To determine the correlation between adjuvanticity and mitogenicity of LPS, spleen cells from normal mice were cultured in the presence of LPS and ³H-thymidine uptake was measured. Spleen cells of DDD mice incorporated three times as much ³H-thymidine as those of C57BL/6 mice. There seems no strong correlation between both activities of LPS. The data obtained are discussed in terms of strain differences in the macrophage function for processing the antigen.     

IgM rheumatoid factors in mice injected with bacterial lipopolysaccharides.

Bacterial lipopolysaccharides (LPS) induced the formation of IgM rheumatoid factors (RF) in several strains of mice including athymic C57BL/6 nude mice, but not in the LPS-resistant C3H/HeJ mice. The RF induced by LPS reacted not only with murine IgG but also with IgG from cows, goats, guinea pigs, and humans. The kinetics of this RF response to injection of LPS were similar to those of antibody response against DNA and a hapten, dinitrophenyl (DNP), and to those of total IgM production. In addition, the RF activity of individual serum samples correlated significantly with levels of anti-DNA and anti-DNP antibodies and of IgM. Therefore, it is concluded that the induction of RF results from polyclonal antibody synthesis by B cells stimulated with LPS. This observation suggests that LPS or LPS-like substances may help to generate RF in patients with rheumatoid arthritis or with some infectious diseases.     

Immunosuppressive Effect of Bacterial Lipopolysaccharide on Antibody Response

Injection of endotoxins (bacterial lipopolysaccharide: LPS) several days prior to immunization causes the suppression of antibody response. The suppressive effects of several kinds of LPS preparations on the plaque-forming cell (PFC) antibody response in the spleen of mice were examined after immunization with sheep red blood cells (SRBC). Glycolipids obtained from heptoseless mutants (Re form) of salmonella or its lipid A preparation coupled artificially with bovine serum albumin (BSA) are capable, like LPS obtained from a wild type (S form) strain, of inducing suppression of the PFC response, while alkaline-detoxified LPS can not. The refractory periods of the PFC response induced by LPS injection last only a few days. However, the use of cyclophosphamide (CY) together with LPS can extend the refractory periods of antigenic stimulation for several weeks. Injections of LPS and CY can also induce unresponsive states of OH agglutinin antibody response to antigenic stimulation with formalin-killed organisms of Escherichia coli or Salmonella enteritidis (presumably both thymus-independent antigens). These unresponsive states induced by LPS and CY are easily terminated by a transfer of syngeneic bone marrow cells but not by thymocyte transfer.     

Effect of bacterial lipopolysaccharides on anti-trinitrophenyl antibody-producing cells. Nonspecific modification of the affinity at the cellular level.

The effect of lipopolysaccharide (LPS) on anti-trinitrophenyl (TNP) direct plaque-forming cells (PFC) in the spleen of mice and the affinity of antibodies produced by these PFC were examined. Simultaneous injection of bacterial LPS and TNP-coupled sheep red blood cells(SRBC) induced an obvious increase in anti-TNP PFC numbers and heightened the antibody affinity at cellular levels. The higher the doses of LPS, the greater the effects. Concomitant injection of LPS in TNP-coupled homologous mouse red blood cells (MRBC) also elicited good anti-TNP PFC response and slightly heightened the affinity. Priming with LPS and SRBC together 7 days prior to immunization did not enhance the anti-TNP PFC response and it was difficult to alter the affinity. Preinjection with small amounts of TNP-MRBC or -rabbit red blood cells and LPS simultaneously did not induce any significant increase in anti-TNP PFC secondary response after reimmunization with TNP-SRBC, but obviously heightened the antibody affinity. Injection of LPS simultaneously with the secondary immunization was effective for both the anti-TNP PFC response and the alteration of antibody affinity. These results suggest that LPS affects the control mechanisms of anti-TNP antibody affinity via the non-thymus-derived helper cell function, and the adjuvant action and alteration of antibody affinity induced by LPS are regulated by different mechanisms.     

Effect of Bacterial Lipopolysaccharides on Anti-Trinitrophenyl Antibody-Producing Cells

The effect of lipopolysaccharide (LPS) on anti-trinitrophenyl (TNP) direct plaque-forming cells (PFC) in the spleen of mice and the affinity of antibodies produced by these PFC were examined. Simultaneous injection of bacterial LPS and TNP-coupled sheep red blood cells(SRBC) induced an obvious increase in anti-TNP PFC numbers and heightened the antibody affinity at cellular levels. The higher the doses of LPS, the greater the effects. Concomitant injection of LPS in TNP-coupled homologous mouse red blood cells (MRBC) also elicited good anti-TNP PFC response and slightly heightened the affinity. Priming with LPS and SRBC together 7 days prior to immunization did not enhance the anti-TNP PFC response and it was difficult to alter the affinity. Preinjection with small amounts of TNP-MRBC or -rabbit red blood cells and LPS simultaneously did not induce any significant increase in anti-TNP PFC secondary response after reimmunization with TNP-SRBC, but obviously heightened the antibody affinity. Injection of LPS simultaneously with the secondary immunization was effective for both the anti-TNP PFC response and the alteration of antibody affinity. These results suggest that LPS affects the control mechanisms of anti-TNP antibody affinity via the non-thymus-derived helper cell function, and the adjuvant action and alteration of antibody affinity induced by LPS are regulated by different mechanisms.     

Cholera toxin modulates the systemic immune responses against Vibrio cholerae surface antigens after repeated inoculations

The immunomodulating properties of a low cholera toxin (CT) dose over the systemic antibody response against Vibrio cholerae antigens after a comparatively extensive period of time were evaluated. Groups of 10 mice were injected intraperitoneally three times at 0, 30 and 86 days with 500 microl of buffer or 10(8) viable recombinant V. cholerae bacteria (lacking cholera toxin A subunit) with or without 100 ng of CT. Sera were obtained from inoculated mice at 0, 14, 28, 37, 58, 80, 93, 114, 236 and 356 days after the first injection. Vibriocidal activity and IgM and IgG anti-lipopolysaccharide (LPS) or outer membrane protein (OMP) antibodies levels were estimated by ELISA in sera of inoculated mice. Anti-LPS IgG subclasses were measured 2 weeks after each immunization by ELISA. Treatment of mice with CT markedly influenced the immune response to LPS but not against OMP of V. cholerae. Simultaneous intraperitoneal administration of CT with V. cholerae resulted in marked enhancement of both IgM anti-LPS and vibriocidal titers which subsisted for a relatively extensive period of time after repeated antigen administration. No differences were observed in IgM and IgG anti-OMP titers after extended periods of time between CT and control treatments. A similar pattern of IgG anti-LPS subclasses was observed in the serum samples analyzed. These results suggest that long term CT administration modulates the IgM anti-V. cholerae LPS response and the serum vibriocidal activity.     

Relation between Enhanced Antibody Responses Elicited by Adjuvant Injection and Those Elicited by Secondary Antigenic Stimulation

An attempt was made to determine if there is any common mechanism in the enhanced antibody response caused either by injection of adjuvant, such as bacterial endotoxin (LPS) and complexed polynucleotides, or by secondary antigenic stimulation. LPS inoculated in mice 4 days before injection of sheep red blood cells (SRBC) and polyA:U invalidated the adjuvant effect of polyA:U injected together with SRBC, and the hemolysin plaque-forming cell (PFC) response of such mice was similar to that of the mice which received SRBC alone. When mice primed with SRBC 24 days in advance were injected with LPS and 4 days later re-stimulated with SRBC, their PFC response to the secondary stimulation was suppressed to less than one tenth of the normal secondary PFC response. The suppressive effect of LPS on the secondary antibody response was abolished if the serum collected from mice injected with LPS was given to the primed and LPS-injected mice at the time of the secondary antigenic stimulation. From these results we discussed the possibility that some common mediator might play a role in the enhanced antibody response elicited by either adjuvant injection or secondary injection of antigen.     

Effect of saccharide length on the immunogenicity of neoglycoconjugates from synthetic fragments of the O-SP of Vibrio cholerae O1, serotype Ogawa

A synthetic hexasaccharide, identical to the terminal hexasaccharide of Ogawa LPS, coupled to bovine serum albumin induced protective antibodies in mice. To determine if there was a minimum saccharide length required for immunogenicity and efficacy, shorter (mono- to pentasaccharide) neoglycoconjugates (CHO-BSA) were tested in mice. The Ogawa CHO-BSA was inoculated at either a constant mass but differing moles, or equal moles but differing masses. Humoral responses were essentially the same when mice received 9 microg of the carbohydrate (0.007 mM with the pentasaccharide) in each of the neoglycoconjugates prepared from mono- through the pentasaccharide, or the same molar amount (0.007 mM), proportionally less by weight when going from the penta- to the monosaccharide. These data show that, within this dose range, the responses occurred virtually independently of the amount of immunogen. Humoral antibodies induced by these immunogens were generally not vibriocidal. Selected antisera induced by CHO-BSA immunogens were protective, but the ELISA titers of the sera were not predictive of the protective capacity. Purified, Ogawa LPS induced anti-Ogawa LPS IgM antibody titers similar to those induced by the Ogawa CHO-BSA conjugates. The anti-whole LPS sera were strongly vibriocidal, as were the previously reported sera induced by hexasaccharide conjugates. This suggests either that the shorter oligosaccharides lack a conformational epitope provided by the hexasaccharide or that the LPS has additional B cell epitopes or selects different B cells in the primary response.     

Can tolerant allogeneic cells restore nude mice?

BALB/c-nunu mice have been injected with allogeneic or tolerant allogeneic spleen or thymus cells and sheep red blood cells (SRBC). From day 3 to day 10 the mice were bled daily and the antiSRBC antibody was assayed by hemagglutination. No difference was found between recipients of normal allogeneic cells or tolerant allogeneic cells. Both showed a transient response but the response was maintained only in recipients of congenic cells.     

Pulmonary lipopolysaccharide (LPS)-binding protein inhibits the LPS-induced lung inflammation in vivo

LPS-binding protein (LBP) facilitates the interaction of the Gram-negative cell wall component LPS with CD14, thereby enhancing the immune response to LPS. Although lung epithelial cells have been reported to produce LBP in vitro, knowledge of the in vivo role of pulmonary LBP is limited. Therefore, in the present study we sought to determine the function of pulmonary LBP in lung inflammation induced by intranasal administration of LPS in vivo. Using LBP-deficient (LBP-/-) and normal wild-type mice, we show that the contribution of LBP to pulmonary LPS responsiveness depended entirely on the LPS dose. Although the inflammatory response to low dose (1 ng) LPS was attenuated in LBP-/- mice, neutrophil influx and cytokine/chemokine concentrations in the bronchoalveolar compartment were enhanced in LBP-/- mice treated with higher (>10 ng) LPS doses. This finding was specific for LBP, because the exogenous administration of LBP to LBP-/- mice reversed this phenotype and reduced the local inflammatory response to higher LPS doses. Our results indicate that pulmonary LBP acts as an important modulator of the LPS response in the respiratory tract in vivo. This newly identified function of pulmonary LBP might prove beneficial by enabling a protective immune response to low LPS doses while preventing an overwhelming, potentially harmful immune response to higher doses of LPS.     

Production of murine collagen-induced arthritis using Klebsiella pneumoniae O3 lipopolysaccharide as a potent immunological adjuvant.

Collagen-induced arthritis (CIA) was produced in mice with non H-2q and H-2r haplotypes by repeated immunization of porcine type-II collagen (CII) together with Klebsiella O3 lipopolysaccharide (KO3 LPS) as an immunological adjuvant. Histological changes that appeared in joints of repeatedly immunized mice were characterized by destruction of normal joint structure, synovial hyperplasia with proliferation of synovial cells, and infiltration of inflammatory cells. No such lesions were produced in mice receiving repeated injections of CII alone or KO3 LPS alone. Development of the humoral antibody and the delayed-type hypersensitivity to CII was exclusively found in mice immunized with the mixture of CII and KO3 LPS. It was therefore suggested that arthritis lesions induced by repeated immunization with the mixture of CII and KO3 LPS might be caused by an autoimmune mechanism, and that the experimental model might be useful for characterization of human rheumatoid arthritis (RA).     

Static and dynamic mechanics of the murine lung after intratracheal bleomycin

Background

Endotoxins are ubiquitously present in the environment and constitute a significant component of ambient air. These substances have been shown to modulate the allergic response, however a consensus has yet to be reached whether they attenuate or exacerbate asthmatic responses. The current investigation examined whether reducing the concentration of lipopolysaccharide (LPS) in a house dust extract (HDE) containing high concentrations of both cockroach allergens [1] and LPS would attenuate asthma-like pulmonary inflammation.

Methods

Mice were sensitized with CRA and challenged with the intact HDE, containing 182 ng of LPS, or an LPS-reduced HDE containing 3 ng LPS, but an equivalent amount of CRA. Multiple parameters of asthma-like pulmonary inflammation were measured.

Results

Compared to HDE challenged mice, the LPS-reduced HDE challenged mice had significantly reduced TNFα levels in the bronchoalveolar lavage fluid. Plasma levels of IgE and IgG1 were significantly reduced, however no change in CRA-specific IgE was detected. In HDE mice, plasma IgG2a levels were similar to naïve mice, while LPS-reduced HDE mice had significantly greater concentrations. Reduced levels of LPS in the HDE did not decrease eosinophil or neutrophil recruitment into the alveolar space. Equivalent inflammatory cell recruitment occurred despite having generally higher pulmonary concentrations of eotaxins and CXC chemokines in the LPS-reduced HDE group. LPS-reduced HDE challenge induced significantly higher concentrations of IFNγ, and IL-5 and IL-13 in the BAL fluid, but did not decrease airways hyperresponsiveness or airway resistance to methacholine challenge. Conclusion: These data show that reduction of LPS levels in the HDE does not significantly protect against the severity of asthma-like pulmonary inflammation.     

Production of IgG antibodies and enhanced response of nude mice to DNP-AE-dextran.

DNP-AE-dextran, prepared by the binding of DNP-epsilon-aminocaproyl residues to animoethylated dextran (predominantly alpha-1,6-linked), induced a T-independent anti-DNP antibody response in mice. However, certain differences were observed between the response to this antigen in normal andnude mice. Thus, the antibody titers of nu/nu mice from day 10 to 38 after immunization were significantly higher than those of nu/+ controls. Furthermore, DNP-AE-dextran induced a weak secondary response in nu/+ but not in nu/nu mice. For both thymusless and normal mice the production of IgG in addition to IgM antibodies to DNP-AE-dextran could be established. The former included antibodies of the IgG1 subclass which were considered to be particularly thymus dependent (1). The higher response of nu/nu mice was reflected mainly in the increased production of IgG antibodies. Under the influence of a graft-vs-host reaction, a 10-fold increase in antibody titers to DNP-AE-dextran was observed, due entirely to an enhanced IgG response.