Vanessa L. Peachee

Effects of Administration of a Monoclonal Antibody against Mouse Tumor Necrosis Factor Alpha during Pregnancy and Lactation on the Pre- and Postnatal Development of the Mouse Immune System:

Monoclonal antibodies directed against tumor necrosis factor alpha (TNFα) are currently employed in the treatment of various immune-mediated diseases. These studies were designed to evaluate potential effects of anti-TNFαtreatment in mice during pregnancy and lactation on the development of the immune system in the F1 generation. Pregnant CD-1 mice were treated with vehicle or with 10 or 40 mg/kg of an anti-mouse TNFαmonoclonal antibody (mAb) (cV1q) on days 6, 12, and 18 of gestation and on days 3, 9, and 15 of lactation. Evaluation of immune system functionality was conducted in F1 generation mice at 11 weeks of age. Immune function was evaluated by splenocyte phenotyping, immunoglobulin M (IgM) antibody response to sheep red blood cells (SRBCs), spleen cell proliferative response to anti-CD3, and natural killer cell activity. Treatment of pregnant mice with cV1q produced no adverse effects in the dams and no adverse effects in the F1 generation. In general, the functioning of the immune system of the F1 generation did not appear to be adversely affected following exposure to cV1q in utero and during lactation. The only statistically significant change was a slight (~20%) reduction in the spleen cell expansion in response to SRBC immunization in the female F1 mice from the 40 mg/kg cV1q treatment group. In conclusion, administration of a monoclonal antibody against mouse TNFαduring pregnancy and lactation had little or no effect on selected immune parameters in mice, with only a possible minor attenuation of spleen cell response to immunization noted in the female F1 generation at 11 weeks of age.

Comparison of primary immune responses to SRBC and KLH in rodents.

In rodents, the Plaque Assay, T-dependent antibody response to sheep erythrocytes (SRBC), has been reported to be a sensitive and predictive functional immune assay for detecting immunomodulatory compounds. However, various laboratories have chosen to use ELISA-based assays for evaluating the primary immune response in rodents. The ELISA-based assays offer several advantages over the Plaque Assay, which make them attractive for use in immunotoxicological evaluations. Among the most popular antigens used in the ELISA-based assays are SRBC and more recently KLH. While the Plaque Assay and the ELISA-based assays are both capable of evaluating the humoral immune response, they are measuring different endpoints. The Plaque Assay focuses primarily on splenic effects. ELISA-based assays, which use serum from immunized animals, are holistic in nature in that these assays measure effects of antibody production on the spleen, lymph nodes, and bone marrow. Depending on the drug or compound evaluated, different effects and degrees of sensitivity can be seen with the Plaque Assay and ELISA-based assays. One recent finding is that the sensitizing dose of KLH used in the KLH ELISA differentially affects the responses observed in rodents. Even within the same species, different strains of mice and rats produce different magnitudes of responses to the same sensitizing dose. A key component of this discussion focuses on the sensitivity of the Plaque Assay as compared to KLH ELISA-based assays. These assays were evaluated by comparing the response obtained following administration of several known immunosuppressive agents, including cyclophosphamide, azathioprine, cyclosporine A and dexamethasone. The effects on the primary IgM immune response in the B6C3F1 mice, the primary immunotoxicological rodents used by National Toxicology Program, and in the Sprague–Dawley rat, the primary rodent models used by industry are addressed.

Thalidomide modulation of the immune response in female B6C3F1 mice: a host resistance study

Previously, we have reported that thalidomide (Thd) treatment can modulate the immune responses in female B6C3F1 mice. The present study was designed to evaluate whether or not these immunomodulatory responses were of sufficient magnitude to alter host resistances in a number of pathogen and tumor models. B6C3F1 mice were treated intraperitoneally with Thd (30-150 mg/kg) for 14 or 28 days, then inoculated with either Plasmodium yeolii, PYB6 fibrosarcoma tumor cells, B16F10 melanoma tumor cells, Listeria monocytogenes, or Streptococcus pneumoniae. Significant dose-dependent protection against B16F10 and L. monocytogenes was observed in mice that were treated with Thd. Furthermore, time course study using bacterial colony-forming units per spleen and liver as the endpoints indicated that the protective effect of Thd on host resistance to L. monocytogenes was time-dependent. In contrast, Thd treatment did not affect host resistance to P. yeolii, S. pneumoniae and PYB6 tumor. Additionally, the effect of Thd on the phagocytic function of the mononuclear phagocyte system (MPS) was evaluated following intravenous injection of 51Cr-labeled sRBCs. The overall phagocytic activity of MPS was not significantly altered by Thd treatment. In conclusion, these results demonstrate that Thd immunomodulation altered host resistance to B16F10 and L. monocytogenes; and selective modulation of Thd on the immune system may be responsible for the pathogen or tumor-specific effect of this compound.

Immunotoxicity Evaluation of Jet A Jet Fuel in Female Rats After 28-Day Dermal Exposure

The potential for jet fuel to modulate immune functions has been reported in mice following dermal, inhalation, and oral routes of exposure; however, a functional evaluation of the immune system in rats following jet fuel exposure has not been conducted. In this study potential effects of commercial jet fuel (Jet A) on the rat immune system were assessed using a battery of functional assays developed to screen potential immunotoxic compounds. Jet A was applied to the unoccluded skin of 6- to 7-wk-old female Crl:CD (SD)IGS BR rats at doses of 165, 330, or 495 mg/kg/d for 28 d. Mineral oil was used as a vehicle to mitigate irritation resulting from repeated exposure to jet fuel. Cyclophosphamide and anti-asialo GM1 were used as positive controls for immunotoxic effects. In contrast to reported immunotoxic effects of jet fuel in mice, dermal exposure of rats to Jet A did not result in alterations in spleen or thymus weights, splenic lymphocyte subpopulations, immunoglobulin (Ig) M antibody-forming cell response to the T-dependent antigen, sheep red blood cells (sRBC), spleen cell proliferative response to anti-CD3 antibody, or natural killer (NK) cell activity. In each of the immunotoxicological assays conducted, the positive control produced the expected results, demonstrating the assay was capable of detecting an effect if one had occurred. Based on the immunological parameters evaluated under the experimental conditions of the study, Jet A did not adversely affect immune responses of female rats. It remains to be determined whether the observed difference between this study and some other studies reflects a difference in the immunological response of rats and mice or is the result of other factors.

Characterization of the T-dependent antibody response (TDAR) to keyhole limpet hemocyanin (KLH) in the Göttingen minipig

Abstract Recently, there has been a renewed interest in the use of the minipig as an alternative to dogs and non-human primates for conducting toxicological assessments in non-rodent species. Since the T-dependent antibody response (TDAR) is one of the most widely-accepted assays used in the assessment of immunocompetence, the present study was undertaken to characterize the primary and secondary TDAR to keyhole limpet hemocyanin (KLH) in the Göttingen Minipig®. Following primary immunization with either 2 or 10 mg KLH, anti-swine IgM and IgG ELISAs were optimized and individual animal responses were evaluated over time. Immunization with 10 mg KLH on Day 0 promoted primary IgM responses that peaked 6–9 days after antigen administration, while primary IgG levels peaked on Day 13 or 14. Secondary IgG antibody levels (following secondary injection with 2 mg KLH on Day 14) plateaued on Days 20–22. Anti-KLH antibody levels were decreased in minipigs treated with cyclophosphamide (CPS), a known immunosuppressant, at doses ranging from 12.5–50 mg/kg/day, while antibody levels in animals treated with 2.5 mg CPS/kg/day were similar to levels in saline-treated swine. These results demonstrate that the Göttingen Minipig® can be a useful alternative non-rodent species to the dog and the non-human primate for evaluating the TDAR to KLH in regulatory assessments of immunotoxicity.

Oral subchronic immunotoxicity study of ethyl tertiary butyl ether in the rat

The potential for immunotoxicological effects of ethyl tertiary butyl ether (ETBE, CAS RN 637-92-3) was studied in young adult female Crl:CD(SD) rats following subchronic oral exposures. Rats were exposed by gavage once daily for 28 consecutive days to 0, 250, 500, or 1000 mg ETBE/kg body weight (BW)/day; a concurrent positive control group received four intraperitoneal injections of at 50 mg cyclophosphamide monohydrate (CPS)/kg/day on study Days 24–27. Immunotoxicity was evaluated using a splenic antibody-forming cell (AFC) assay to assess T-cell-dependent antibody responses in rats sensitized with sheep red blood cells (SRBC). All rats survived to the scheduled necropsy. There were no effects on clinical observations, body weights, feed or water consumption, or macroscopic pathology findings in the ETBE-treated rats. No ETBE-related effects were observed on absolute or relative (to final body weight) spleen or thymus weights, spleen cellularity, or on the specific (AFC/106 spleen cells) or total activity (AFC/spleen) of splenic IgM AFC to the T-cell-dependent antigen SRBC. CPS produced expected effects consistent with its known immunosuppressive properties and validated the appropriateness of the AFC assay. Based on the results of this study, ETBE did not suppress the humoral component of the immune system in female rats. The no-observed-effect level for immunotoxicity was the highest dosage tested at 1000 mg/kg/day.

Validation of a Candida albicans delayed-type hypersensitivity (DTH) model in female juvenile rats for use in immunotoxicity assessments

Abstract Establishing an in vivo cell-mediated immunity (CMI) assay, such as the delayed-type hypersensitivity (DTH) assay, has been identified as an important gap and recommended to receive highest priority for new model development in several workshops on developmental immunotoxicity. A Candida albicans DTH model has recently been developed that has the advantage over other DTH models, which use alternative sensitizing antigens, in that antigen-specific antibodies, which may interfere with the assay, are not produced. In addition, the in vivo C. albicans DTH model was demonstrated to be more sensitive in detecting immunosuppression than DTH models using keyhole limpet hemocyanin (KLH) or sheep red blood cells as antigens, as well as some ex vivo CMI assays. While KLH and sheep red blood cells are non-physiological immunogens, C. albicans is an important human pathogen. The present studies were conducted in order to optimize and validate the C. albicans DTH model for use in developmental immunotoxicity studies using juvenile rats. Three known immunosuppressive compounds with different mechanisms of action were tested in this model, cyclosprorin A (CsA), cyclophosphamide (CPS), and dexamethasone (DEX). Animals were sensitized with formalin-fixed C. albicans on postnatal day (PND) 28 and challenged with chitosan on PND 38. Drug was administered beginning on PND 23 and continued until PND 37. Exposure to each of the three immunotoxicants resulted in statistically significant decreases in the DTH response to C. albicans-derived chitosan. Decreases in footpad swelling were observed at ≥10 mg CsA/kg/day, ≥5 mg CPS/kg/day, and ≥0.03 mg DEX/kg/day. These results demonstrate that the C. albicans DTH model, optimized for use in juvenile rats, can be used to identify immunotoxic compounds, and fills the need for a sensitive in vivo CMI model for assessments of developmental immunotoxicity. Abbreviations Ab, antibody APC, antigen presenting cell BSA, bovine serum albumin C. albicans, Candida albicans CI, challenge interval CMI, cell-mediated immunity CO, challenge only CPS, cyclophosphamide CsA, cyclosporin A CTL, cytotoxic T lymphocyte DEX, dexamethasone DIT, developmental immunotoxicity DTH, delayed-type hypersensitivity ip, intraperitoneal KLH, keyhole limpet hemocyanin MLR, mixed lymphocyte reaction OVA, ovalbumin PBS, phosphate-buffered saline PND, postnatal day sc, subcutaneous SEM, standard error of the mean SRBC, sheep red blood cells