Development of human lymphocyte-engrafted SCID mice as a model for immunotoxicity assessment.

Mice with the severe combined immunodeficient (SCID) and triple-deficient (bg/nu/xid) mutations lack select populations of functional immune cells. Studies by several laboratories have demonstrated the ability to restore certain missing immune components in these mice by reconstituting with various lymphoid tissues including peripheral blood lymphocytes (PBL) from mice and humans. Such a model could provide an opportunity to examine human lymphoid cells in an in vivo environment for immunotoxicity assessment. In the present studies, bg/nu/xid and SCID mice were reconstituted by intraperitoneal or intravenous injection with either tetanus-immunized syngeneic mouse splenocytes (mo-SPL) or tetanus-immunized human PBLs (hu-PBL) under various test conditions. Hu-PBL-SCID mice from the C.B-17 strain produced more successful human engraftments than mice from the bg/nu/xid or C3H-SCID strains. Using optimal conditions, mo-SPL-SCID and hu-PBL-SCID mice were engrafted and administered either 2,3,7,8-tetrachlorodibenzo-p-dioxin or cyclosporin A (Cys A) and periodically bled to measure tetanus-specific antibody and class-specific immunoglobulin concentrations. Comparison of the chemical-related changes in immunoglobulin and tetanus antibody concentrations revealed some similarities between control mice and mo-SPL-SCID or hu-PBL-SCID mice, particularly with Cys A groups. However, under the various conditions examined, hu-PBL-SCID mice demonstrated considerable variability in their ability to provide consistent reconstitution, thus, limiting the ability to determine whether human cells are more or less susceptible than mouse cells to the test agents. Provided that this system can be refined to provide consistent reconstitution, hu-PBL-SCID mice may be a promising in vivo model for assessment of potential immunotoxic agents.

Topical application of T-2 toxin inhibits the contact hypersensitivity response in BALB/c mice.

T-2 toxin, a trichothecene mycotoxin, has previously been shown to alter immune functions and promote skin tumors. We demonstrate that topically applied T-2 toxin reduces the ear swelling response to oxazolone challenge in BALB/c mice. For this reduction in ear swelling to occur, toxin application must be at, or within, 1 h after challenge. Dose-response studies showed a 44% reduction in ear swelling with 30 ng of T-2 toxin as compared with a similar reduction with 300 ng of dexamethasone. T-2 toxin did not affect Ag transport from the challenge site to the draining lymph nodes as measured by FITC transport. However, T-2 toxin significantly reduced both MHC class II (Ia) expression and Ag presentation at the same concentrations. Because T-2 toxin, a known protein synthesis inhibitor, was found to inhibit protein synthesis in epidermal cell cultures as measured by [3H]-leucine incorporation, cycloheximide was also examined. Cycloheximide reduced both oxazolone-induced ear swelling and Ag presentation in a similar manner to T-2 toxin. One mechanism of action for T-2 toxin in reducing the contact hypersensitivity response is via inhibition of protein synthesis and effective Ag presentation by epidermal Langerhans cells. This may involve alterations in Ia Ag expression, although a role for class II in the induction phase of the contact hypersensitivity response has not been established definitively.

Thymocyte injury after in vitro chemical exposure: potential mechanisms for thymic atrophy.

In addition to hepatic injury, thymic atrophy is a common observation in rodent subchronic toxicity studies. We have examined representative chemicals which produce thymic atrophy in rodents for their ability to cause direct thymocyte injury because the mechanism(s) responsible for these effects have not been determined. Although a number of the compounds examined failed to have any observable direct effect on thymocytes, others either inhibited lymphocyte proliferation or initiated cell death. In the latter group, thymocyte death was always preceded by increases in intracellular Ca++ and involved, to varying degrees, necrotic and apoptotic events. Apoptosis, as evidenced by cellular DNA cleavage into multiples of 180-200-base pair oligonucleotides and partial cell protection by cycloheximide treatment, was most evident after treatment with acetaldehyde or dibutyltin dichloride. A number of compounds that produce thymic atrophy also inhibited T lymphocyte proliferation without evidence of cell death. Considering that many of the compounds tested failed to produce any evidence of direct thymocyte injury (i.e., necrosis, apoptosis or inhibition of cell proliferation), indirect mechanisms may also be involved in thymic atrophy and may target prothymocytes in the bone marrow, after normal homing patterns or injure the thymic epithelium. Thus, it appears that a variety of mechanisms may be responsible for chemical-induced thymic atrophy and/or injury.