Neoplastic and nonneoplastic lesions in aging mice of unique and common inbred strains contribution to modeling of human neoplastic diseases.

The evaluation of spontaneous lesions in classical inbred strains of mice has become increasingly important because genetically engineered mice (GEMs) are created on these backgrounds. Novel inbred strains-genetically diverse from classic strains-are valuable both as a new background for GEM mice and to increase the genetic variation found in laboratory mice. Newly arising spontaneous genetic alterations in commonly used strains may also lead to new and valuable mouse models of disease. This report evaluates gross and histological lesions in relatively new, classic, and rarely explored mouse inbred strains. Pathological lesions of 1273 mice from 12 inbred strains (129S1/SvW, A.CA-H2(f) /W, AKR/W, BALB/cW, BN/aW, C57BL/6 W, C57BL/10 W, C3H/W, C3H (wad) /W, CBA/W, DBA/2 W, and WOM/W) are reported. BN/aW, WOM/W, and C3H (wad) /W are novel inbred strains produced and maintained in the Department of Genetics and Laboratory Animal Breeding at the Center of Oncology, Warsaw, Poland. Both neoplastic and nonneoplastic lesions were examined. The prevalence of lung neoplasms was significantly higher in A.CA-H2(f) /W (33.3%) and BALB/cW (33.8%) mice (P < .01). The prevalence of liver neoplasms was significantly higher in the CBA/W strain (P < .01). Mammary gland neoplasms arose at a greater frequency in C3H/W mice (P < .01). The occurrence of uterine neoplasms was higher in DBA/W and 129S1/SvW mice. AKR/W and WOM/W mice developed T-cell lymphoblastic lymphoma with high frequency (110/121 [90.9%] and 159/175 [90.9%], respectively) before 1 year of age. The occurrence of nonneoplastic lesions in the kidneys of BN/aW mice was increased (P < .01).

Recovery of dendritic cell counts and function in peripheral blood of cancer patients after chemotherapy.

Dendritic cell (DC) counts and function were assayed in peripheral blood of lymphoma and solid tumor patients before and after chemotherapy. The DC counts declined significantly within the first week from the start of chemotherapy, recovered in the second week, and exceeded the baseline values in the third week. DC recovery was usually similar after the first and after the last cycle of chemotherapy. DC1 and DC2 subsets followed the pattern of reconstitution found for the DC population as a whole. Monocytes and granulocytes recovered 1-2 weeks later than DC. The primary proliferative response to keyhole lympet hemocyanin (KLH), totally DC-dependent, declined within the first week from the start of chemotherapy, and in the majority of patients (including those initially unresponsive) recovered along with DC counts. The recovered responsiveness to KLH, but not to anti-CD3 antibody, disappeared at the end of chemotherapy in lymphoma and some solid tumor patients. Prolonged depletion of CD4+ T cells could contribute to the loss of responsiveness in lymphoma patients receiving multiple cycles of chemotherapy. However, in some solid tumor patients, the reactivity to KLH was absent, despite the reconstitution of both DC and CD4+ T-cell counts. Our data show that numerical reconstitution of DC is not necessarily accompanied by functional recovery. The early recovery of DC should be considered while designing protocols for DC collection for immunotherapy.

A method for directly determining the number of dendritic cells and for evaluation of their function in small amounts of human peripheral blood.

Bone marrow-derived dendritic cells (DC) are highly potent antigen-presenting cells (APC) capable of initiating primary responses of naive T lymphocytes to antigen. Studies on DC in disease have been impeded by the lack of a defined method for accurate DC counting and for evaluation of their function in a small amount of blood. In order to detect and enumerate DC in whole peripheral blood preparations, we applied a direct two-color immunofluorescence method. Blood from healthy donors was stained with a mixture of fluorescein isothiocyanate (FITC)-conjugated monoclonal antibodies (mAbs) recognizing lineage-associated molecules (CD3, CD14, CD16, CD20, CD57) and phycoerythrin (PE)-conjugated anti-HLA-DR mAb. DC were identified as lineage marker negative (lin-), HLA-DR highly positive cells. The mean percentage of these cells present in peripheral blood leukocytes (PBL) was 0.54%, and the mean absolute DC count was 31.4 x 10(6)/l of blood. DC stained directly in whole blood were heterogeneous with regard to their expression of CD2 and CD4 molecules, and did not express CD80 and CD83 molecules. Expression of CD80 and CD83 on DC was induced following a multistep isolation procedure, including overnight culture. We demonstrated a significant primary proliferative response to keyhole limpet hemocyanin (KLH) in cultures of peripheral blood mononuclear cells (PBMNC). Since primary proliferative response to neoantigens is entirely dependent on DC as APC, the cultures of unseparated PBMNC stimulated with KLH can be used to evaluate DC function in a relatively simple test. This test does not require previous isolation of DC and T lymphocytes and, therefore, can be performed on a small amount of blood. The elaborated flow cytometric method of DC counting in blood and the proliferative test of DC-dependent primary response to neoantigen are currently being applied in an ongoing study on the effect of chemotherapy on DC number and function in cancer patients.

IgM antibody-dependent cell-mediated cytotoxicity in the Moloney sarcoma virus system: the involvement of T and B lymphocytes as effector cells.

Antibody-dependent cell-mediated cytotoxicity in the Moloney sarcoma virus (MSV) system was analyzed with respect to the subpopulations of effector cells involved in tumor target cell destruction when IgM was used as the sensitizing antibody. With unfractionated sera from animals that had undergone regression primary MSV tumors it was found that macrophages did not contribute to the cytotoxicity induced by normal spleen cells that were syngeneic to the target cells. The IgM fraction of MSV regressor sera was found to induce cytotoxicity against the target cells by immunoadsorbent column-fractionated normal spleen cells, which were either depleted of T cells or B cells, according to the specificity of the columns. Immune IgM was also found to potentiate the activity of MSV regressor spleen cells that had been similarly fractionated. Furthermore, IgM antibody was found to induced cytotoxicity by normal spleen cells which had been depleted of either T or B cells by the appropriate antiserum (anti-T or anti-Ig) in the presence of complement and subsequent recovery of the viable cells by trysinization, filtration, and washing. However, spleen cells treated with both anti-T and anti-Ig sera simultaneously in the presence of complement and subsequet recovery of viable cells, were not induced to be cytotoxic against the IgM-coated tumor target cells. Further support oy T cells was provided by an experiment showing the induction with IgM of cytotoxicity against the target cells by normal thymocytes.

Antibody-dependent lymphocyte cytotoxicity in the murine sarcoma virus system: activity of IgM and IgG with specificity for MLV determined antigen(s).

Antisera with specificity for Moloney leukemia virus-(MLV) determined antigen(s) were studied for their ability to induce MLV antigen bearing target cell reduction by lymphocytes in microcytotoxicity assays. Sera from animals which had regressed Moloney sarcoma virus (MSV) tumors as well as sera from animals with progressively growing MSV tumors were found to induce normal lymphocytes to be active against the targets. Regressor serum was found also to induce cytotoxicity by immune lymphocytes from a tumor-bearing animal 15 days after MSV and from a regressor 50 days after MSV infection. Both the 19S and 7S Sephadex G-200 fractions of the antisera were found to induce cytotoxicity by normal lymphocytes and to potentiate the cytotoxicity of MSV immune lymphocytes. These activities were shown to be IgM and IgG, respectively, by the use of Sepharose-coupled anti-mouse IgM and anti-mouse IgG columns. All activity was removed by passing sera over both columns.

The lymphocyte response to primary Moloney sarcoma virus tumors in BALB-c mice. Definition of the active subpopulations at different times after infection.

Adult BALB/c mice were injected with Moloney sarcoma virus (MSV) after which the animals' lymphocytes were examined for activity against Moloney leukemia virus (MLV) antigen-bearing target cells at 5-day intervals for 30 days. Lymphocytes from these animals and appropriately matched controls were fractionated into B cell-deficient (primarily T cells) and T cell-deficient (primarily B cells) subpopulations. Macrophages were removed using iron powder and magnetism. The unfractionated lymphocytes, T cells, and non-T cells were then tested in microcytotoxicity tests. Antigen-specific activity was found in the unfractionated lymphocytes from animals that had not yet developed palpable tumors and from regressor animals. The T cells were active just before tumor development and just after regression; however, by day 30 after virus infection (8-10 days after regression) the T cell subpopulation was much less active. The non-T cell subpopulation was also active before tumor development and soon after regression. However, this activity continued to rise after regression and was highest at 30 days. At day 15 (peak tumor size) neither subpopulation was active. The activity was demonstrated to be specific for the MLV-determined cell surface antigen by testing on control target cells that were MLV antigen negative and by comparison of the inhibitory effects with lymphocytes immune to a nonpertinent antigen as well as normal lymphocytes. The non-T cells were tested for activity before and after removal of macrophages with iron powder and magnetism. Such cells were significantly more active after removal of the macrophages. These data demonstrate specific T cell and non-T cell activity in microcytotoxicity tests with a tumor-specific system and strongly suggest that the non-T cell activity described herein is a B cell function.