Recombinant human tumor necrosis factor mediates regression of a murine sarcoma in vivo via Lyt-2+ cells

Summary The role of an immune response in recombinant-human-tumor-necrosis-factor(rHTNF)-mediated regression of a weakly immunogenic, MCA-106 sarcoma in vivo was examined. C57BL/6 mice bearing established 10-day s.c. tumor were treated with single i.v. doses (8 g) of rHTNF. rHTNF administration resulted in marked hemorrhagic necrosis and subsequent regression of tumor in treated mice. Mice cured of MCA-106 sarcoma by rHTNF specifically rejected a subsequent challenge (5×10⁵ cells) of the same tumor (P<0.01) but not of the antigenically distinct, syngeneic MCA-105 sarcoma. Tumor bearers were depleted in vivo of selective T-cell subsets by the systemic administration of specific monoclonal antibodies before rHTNF therapy. rHTNF-induced regression, but not hemorrhagic necrosis of the MCA-106 sarcoma was blocked in mice depleted of Lyt-2⁺ cells, but not of L3T4⁺ cells. The in vivo role of T-cell subsets in rHTNF-mediated tumor regression is discussed.Howard Hughes Medical Institute Research Scholar     

Distinct immunologic specificity of tumor regression mediated by effector cells isolated from immunized and tumor-bearing mice

Sensitized T lymphocytes can mediate potent antitumor effects when transferred to tumor-bearing animals. Employing the MCA 105 and MCA 106 sarcomas, we were able to generate antitumor effector cells by immunization of syngeneic mice with tumor cells admixed with Corynebacterium parvum. These immune splenocytes could be further sensitized and expanded in culture by the in vitro sensitization (IVS) method utilizing tumor stimulator cells and IL-2. Adoptive immunotherapy of pulmonary metastases mediated by noncultured splenocytes from immunized mice or immune IVS cells showed exquisite specificity between the two sarcomas. These results demonstrate the presence of tumor-specific antigens on MCA 105 and MCA 106 tumor cells which can serve as target molecules for immunotherapy. Recently, we have generated therapeutic T lymphocytes from mice bearing progressively growing tumors by the IVS method. However, IVS cells from tumor-bearing mice showed cross-reactivity between the MCA 105 and 106 sarcomas in adoptive immunotherapy experiments. Since these IVS cells did not affect other control tumors, the limited cross-reactivity suggests the presence of common tumor-associated antigens on MCA 105 and MCA 106 tumor cells which can also serve as the target for tumor rejection. Therefore, immune responses to progressive tumor growth and to immunization are distinct with respect to antigen recognition by T lymphocytes.     

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)     

Adoptive immunotherapy of murine hepatic metastases with lymphokine activated killer (LAK) cells and recombinant interleukin 2 (RIL 2) can mediate the regression of both immunogenic and nonimmunogenic sarcomas and an adenocarcinoma

The incubation of normal murine splenocytes in recombinant interleukin 2 (RIL 2) gives rise to lymphokine-activated killer (LAK) cells that are specifically cytotoxic to fresh noncultured, autologous, syngeneic, and allogeneic primary and metastatic tumor cells, but are not toxic to normal cells. We have recently shown that the systemic injection of RIL 2 given alone or in conjunction with LAK cells can reduce the number of established pulmonary and hepatic micrometastases from a weakly immunogenic sarcoma in mice. In this report we have analyzed the response of hepatic metastases (HM) induced from both a nonimmunogenic sarcoma (MCA-102) and an adenocarcinoma (MCA-38). Treatment of mice bearing HM from the MCA-102 and MCA-38 tumors revealed that low doses of RIL 2 (5000 to 25,000 U t.i.d.) had little if any anti-tumor effect when given alone (mean percent reduction over control for the MCA-102 tumor: 14%, for the MCA-38 tumor: 10%, p, not significant). Doses of 100,000 U of RIL 2 affected a 38 and 53% reduction in the number of metastases over control for the MCA-102 and MCA-38 tumors, respectively (p less than 0.05). However, when LAK cells were added to the same doses of RIL 2, the corresponding mean percent reduction over control was 90% (p less than 0.005) and 61% (p less than 0.05) for MCA-102 and MCA-38, respectively, at RIL 2 doses of 5000 to 25,000 t.i.d. At doses of 100,000 U of RIL 2 administered with LAK cells, the corresponding percent reductions were 98 and 99%, respectively (p less than 0.005). Therapy with LAK cells plus RIL 2 can also prolong the survival of these mice. In addition, the intraportal administration of LAK cells is more effective than the i.v. administration of these cells. Thus, treatment of established HM from a nonimmunogenic sarcoma and an adenocarcinoma can be successfully mediated by the systemic infusion of LAK cells with RIL 2. These findings provide a rationale for clinical trials of infusion of LAK cells with RIL 2 in the therapy of HM in humans.     

Effector phenotype and immunologic specificity of T-cell-mediated adoptive therapy for a murine tumor that lacks intrinsic immunogenicity

The MCA 102 sarcoma has been defined by a variety of immunologic studies as a tumor lacking intrinsic immunogenicity. Nevertheless, we have recently demonstrated the feasibility of generating therapeutically effective lymphocytes for adoptive immunotherapy of this tumor. Procedures to achieve this required in vivo priming of syngeneic mice to elicit preeffector cells followed by in vitro sensitization (IVS) with tumor cells in the presence of IL-2. By selective depletion of T cell subsets in vivo, we identified the involvement of both CD4+ (L3T4+) and CD8+ (Lyt-2+) T cells in mediating tumor regression. The CD4+ cells exerted their helper function via the secretion of IL-2 because antitumor effects abrogated by depletion of CD4+ cells could be reconstituted by exogenous IL-2. In order to elicit preeffector cells with reactivity against the MCA 102 tumor, we found that in vivo sensitization could be accomplished with either the MCA 102 or MCA 106 tumor but not with the MCA 101 or MCA 105 tumor. Analysis of specificity of tumor stimulation during IVS of MCA 102 tumor-primed preeffector cells demonstrated cross-reactivity between not only the MCA 102 and MCA 106 tumors but also the MCA 105 tumor whereas the MCA 101 tumor was ineffective. In adoptive immunotherapy, transfer of IVS cells generated from MCA 102 tumor-primed and stimulated lymph node cells was able to mediate reductions of pulmonary metastases established from the MCA 102, MCA 105, and MCA 106 tumors but not from the MCA 101 tumor. We conclude that regression of the MCA 102 tumor is probably mediated through T cell recognition of a set of common tumor-associated Ag shared by several other syngeneic tumors. Immunologically, the tumor-associated Ag are characteristically different from classical tumor-specific transplantation Ag (TSTA) because immunity to TSTA on the MCA 105 or MCA 106 tumor does not cross-react with the MCA 102 tumor. Thus, this study demonstrates that Ag other than TSTA on chemically induced tumors can serve as target molecules for T cell-mediated adoptive immunotherapy.     

Evaluation of human carcinoembryonic-antigen (CEA)-transduced and non-transduced murine tumors as potential targets for anti-CEA therapies

The MC-38 C57BL/6 mouse colon adenocarcinoma cell line has been transduced with a retroviral construct containing cDNA encoding the human carcinoembryonic antigen (CEA) gene [Robbins PF, Kantor JA, Salgaller M, Horan Hand P, Fernsten PD, Schlom J (1991) Cancer Res 51: 3657]. Two clones, MC-38-ceal and MC-38-cea2, expressed high levels of CEA on their cell surface. A third CEA-expressing cell line, MCA-102-cea3, was similarly derived by transduction of the MCA-102 C57BL/6 mouse fibrosarcoma cell line and is described here. In this study, the three CEA-transduced murine tumor cell lines (MC-38-cea1, MC-38-cea2, MCA-102-cea3) were evaluated for their tumorigenic potential, as well as their ability to serve as in vivo model systems for active and passive immunotherapy studies. Parameters that were investigated include tumor growth rate, the antibody response of the host to CEA, and the CEA content of the tumors. The MC-38-cea2 model appeared to be the most appropriate for immunotherapy studies. Biodistribution studies, using an¹²⁵I-labeled anti-CEA mAb, demonstrated efficient tumor targeting of MC-38-cea2 tumors in C57BL/6 and athymic mice.     

Generation of therapeutic T lymphocytes from tumor-bearing mice by in vitro sensitization. Culture requirements and characterization of immunologic specificity

We have previously established an in vitro sensitization (IVS) procedure with which lymphocytes from tumor-bearing mice could be expanded and sensitized to acquire antitumor reactivity capable of mediating the regression of established pulmonary metastases from the weakly immunogenic MCA 105 murine sarcoma. Culture conditions required for the optimal generation of therapeutic effector cells were evaluated in the current study. Generation of effector cells by IVS required stimulation by intact tumor cells. Tumor cells killed by heat or disrupted by sonication were ineffective, but the antigenicity of tumor cells was not affected by gamma-irradiation. Long term established tumor cell lines could also serve as antigenic stimulator cells albeit with lower efficiency than fresh tumor cells. IL-2 was essential for cellular proliferation during IVS. The concentration of 1000 U/ml of IL-2 also induced nonspecific lymphokine-activated killer (LAK) activity. However, cytotoxic cells were generated during IVS in response to a broad range of IL-2 concentrations. At low IL-2 concentrations (2 to 10 U/ml), IVS cells were generated which displayed little or no LAK activity, had a greater therapeutic efficacy than those generated with high concentrations of IL-2 (100 to 1000 U/ml). Despite having high LAK activity, IVS cells, from cultures where IL-2 was added 3 or more days after initiation, had no therapeutic effect. Thus, the generation of therapeutic cells occurred independently of LAK cell production. Adoptive immunotherapy with IVS cells from MCA 105 tumor-bearing mice demonstrated cross-reactivity with the immunologically distinct MCA 106 but not the nonimmunogenic MCA 102 tumor. In contrast, IVS cells from MCA 106 tumor-bearing mice exhibited specific in vivo reactivity. In vitro cytotoxicity analyses revealed that IVS cells from MCA 105 and MCA 106 tumor-bearing mice were able to lyse both MCA 105 and MCA 106 target cells, but the reactivity toward inoculating tumors was highest. Considering previous findings that the MCA 105 and MCA 106 sarcomas possessed distinct tumor-specific transplantation Ag, the cross-reactivity observed in this study suggests that the immune response during progressive tumor growth may be different from that elicited in response to active immunization.     

Micro-leukocyte adherence inhibition. I. Cellular basis of the mechanism of reactivity.

To study the cellular basis for specific antigen-induced leukocyte adherence inhibition, enriched populations of B cells, T cells, and monocytes were prepared by a two-stage adherence separation procedure from spleen cells of normal C57BL/6J mice and mice bearing progressively growing MCA-38 tumors. The reactor cell undergoing specific antigen-induced adherence inhibition was identified as a monocyte (esterase positive, did not respond to mitogens, and did not bear Thy 1.2 antigen or surface immunoglobulin). Furthermore, an enriched population of MCA-38 sensitized B cells could program normal monocytes to undergo specific antigen-induced adherence inhibition. This programming could be abolished by pretreatment of the MCA-38 sensitized B cells with anti-immunoglobulin and complement (indirect cytotoxicity method). In contrast, enriched populations of MCA-38 sensitized T cells could not program normal nylon wool adherent cells to undergo antigen-specific adherence inhibition; and anti-Thy 1.2 serum and complement had no effect on specific antigen-induced adherence inhibition. Thus, in this murine tumor model, leukocyte adherence inhibition appears to be due to the programming of monocytes by sensitized B cells.     

Cross-reacting antigens in chemically induced sarcomas are fetal determinants.

Serologic cross-reactivity has been demonstrated among three MCA-induced sarcomas in C57BL/6N female mice (MCA-2, MCA-3, and MCA-12) with a microcytotoxicity assay. Serum from mice bearing MCA-3 tumor was cytotoxic to both MCA-2 and MCA-3 tumor cells at a titer of 1:8. Sequential absorptions of this serum with syngeneic embryo cells completely eliminate cytotoxicity against MCA-2 cells without affecting the cytotoxic titer against MCA-3 cells. Serum hyperimmune to the MCA-3 tumor reacted with MCA-3, MCA-2, and MCA-12 tumors. Absorption of this serum with embryo cells eliminated cytotoxicity against MCA-2 and MCA-12 cells, but was incapable of lowering the titer against MCA-3 cells below 1:40. Similarly, serum hyperimmune to MCA-2 tumor was lytic to MCA-2, MCA-3, and MCA-12 before absorption, but was lytic only to MCA-2 cells after absorption with sygeneic embryo cells. Thus, the in vitro cross-reactivity between MCA-induced sarcomas is due to a common fetal antigen(s), which is distinct from the individual tumor-specific antigens of each tumor. Since these tumors do not exhibit cross-reactivity in in vivo challenge experiments, it appears that this fetal antigen is not responsible for in vivo immune protection.     

In vivo induction of IL-6 by administration of exogenous cytokines and detection of de novo serum levels of IL-6 in tumor-bearing mice

We investigated the capacity of several recombinant cytokines to induce IL-6 in vivo in both normal and tumor-bearing (TB) mice. Intravenous administration of human rhTNF-alpha, rhIL-1, rhIL-2, rhIFN-alpha A/D, and rmIFN-gamma were all capable of inducing circulating IL-6. rhTNF-alpha administration caused the greatest induction of IL-6. TB animals consistently produced more IL-6 in response to rhTNF-alpha than did normal mice (2 h after 4 micrograms rhTNF-alpha, TB = 24,100 HGF U/ml, non-TB = 3600 HGF U/ml of IL-6). A single daily i.v. dose of rhTNF-alpha (4 micrograms/mouse/day) for 5 days led to decreased IL-6 induction in TB animals by day 3 of treatment (peak levels of IL-6, day 1 = 72,800 HGF U/ml, day 3 = 23,400 HGF U/ml, day 5 = 26,400 HGF U/ml). rhIL-1 administration also resulted in considerable IL-6 production, although peak values were less than those resulting from administration of rhTNF-alpha. Administration of rhIL-1 induced similar IL-6 levels (TB = 10,025 and non-TB = 10,600 HGF U/ml) in TB and normal mice. Single high doses of rhIL-2, rhIFN-alpha A/D, and rmIFN-gamma induced lower but consistent levels of circulating IL-6 in mice with and without tumor. In addition, the sera of untreated TB mice contained levels of IL-6 which paralleled the extent of tumor burden (serum IL-6 in day 30 MCA 106 TB mice = 420 HGF U/ml). The detection of de novo IL-6 was also confirmed in animals bearing tumors of different histologies (the MCA 102 sarcoma, MCA 38 adenocarcinoma, and B16 melanoma). At no time was IL-6 measurable in the sera of untreated normal mice. The identification of IL-6 was verified by neutralization studies using specific antimurine IL-6 antibody. Although the exact role of IL-6 in TB animals remains to be elucidated, its known pleotrophic immune and metabolic effects may be important in the host response to malignancy.     

Protection against gram-negative bacteremia in neutropenic mice with recombinant granulocyte-macrophage colony-stimulating factor

Granulocyte-macrophage colony-stimulating factor (GM-CSF) stimulates production of neutrophils in bone marrow and may decrease the incidence of infection during neutropenia. We evaluated the protective role of recombinant GM-CSF against Pseudomonas aeruginosa challenge in neutropenic mice. CD-1 mice treated with cyclophosphamide on days 1 and 2 of the experiment were given GM-CSF (1, 2, or 4 micrograms/day) starting at day 4 of the experiment according to the following protocol: 1) 1 microgram of GM-CSF 2 hr and 24 hr after challenge; 2) 1 microgram 24 hr before challenge, 2 hr and 24 hr after challenge; 3) 2 micrograms injected 24 hr before and 2 hr after challenge; 4) 2 micrograms given 24 hr before and 2 micrograms given 2 hr and 24 hr after challenge; 5) 4 micrograms administered 2 hr and 24 hr after challenge; and 6) saline and bovine albumin controls. The number of blood neutrophils by days 4 and 5 was similar for GM-CSF-treated and untreated animals. Survival was significantly greater in animals given 2 micrograms of GM-CSF at 24 hr before and at 2 hr and 24 hr after challenge with Pseudomonas. Neutrophils and splenic macrophages obtained from GM-CSF-treated mice (2 micrograms/animal) produced significantly greater amounts of O2- (204 +/- 36 nmoles/10(5) cells) than controls (21 +/- 10 nmoles/10(5) cells). Additionally, neutrophils and macrophages from GM-CSF-treated mice killed significantly more bacteria (P. aeruginosa) in vitro and had a greater number of C3b and Fc receptors (78 +/- 12% and 89 +/- 8%) than did cells obtained from control animals.(ABSTRACT TRUNCATED AT 250 WORDS)     

Identification of cellular mechanisms operational in vivo during the regression of established pulmonary metastases by the systemic administration of high-dose recombinant interleukin 2

The systemic administration of high-dose recombinant IL 2 mediated significant reductions of established 3-day pulmonary micrometastases from both weakly immunogenic and nonimmunogenic sarcomas. However, when treatment with IL 2 was delayed for 10 days after the injection of tumor cells in an attempt to treat grossly visible pulmonary macrometastases, only those established from weakly immunogenic sarcomas remained susceptible. Established 10-day pulmonary nodules from the nonimmunogenic sarcomas became refractory to IL 2 therapy. We utilized selective depletion of lymphocyte subsets in vivo by the systemic administration of specific monoclonal antibodies to cells bearing either the L3T4 or Lyt-2 marker or a heteroantiserum to cells bearing the ASGM-1 glycosphingolipid to identify lymphocytes involved in IL 2-induced tumor regression. Cells with potent lymphokine-activated killer (LAK) activity against fresh tumor targets in vitro were identified in the lungs of IL 2-treated mice. By flow cytometry analysis, the majority of these effector cells were Thy-1+, L3T4-, Lyt-2-, ASGM-1+. Depletion in vivo of ASGM-1+ cells before the onset of IL 2 administration eliminated the successful therapy of 3-day pulmonary metastases from nonimmunogenic sarcomas, with concurrent elimination of LAK cell activity in the lungs. In mice with 3-day pulmonary metastases from weakly immunogenic sarcomas, both Lyt-2+ cells and ASGM-1+ cells were involved in IL 2-mediated tumor regression, but Lyt-2+ cells appeared to be the more potent mediator in the response. Lyt-2+ cells were also involved in the elimination of grossly visible 10-day macrometastases from these weakly immunogenic tumors. Depletion of L3T4+ cells had no effect on tumor regression. Thus, although LAK effectors derived from ASGM-1+ precursors can eliminate pulmonary micrometastases regardless of tumor immunogenicity, Lyt-2+ cells are predominant effectors in the elimination of both pulmonary micro- and macrometastases from weakly immunogenic sarcomas.     

Inhibition of liver metastases in murine colon adenocarcinoma by liposomes containing human C-reactive protein or crude lymphokine

Previous studies from our laboratory have shown that liposomes containing LYNK or CRP inhibit lung metastases in mice bearing the malignant fibrosarcoma, T241. We have now extended these observations to the murine colon adenocarcinoma (MCA-38), which metastasizes to the liver. MCA-38 tumor cells (1 X 10(6)) were implanted in the wall of the cecum by orthotopic transplantation. Three-hundred twenty-six mice bearing such tumors were divided into four treatment groups as follows: (1) no treatment (2) liposomes containing control medium (3) liposomes containing LYNK, and (4) liposomes containing CRP. Treatment was started from day 2, day 18, or 34 after tumor implantation and it was administered on 3 days per week. Each treatment, given parenterally, consisted of 4 mumol liposomes (PS-PC, 1:1) containing the appropriate agents. Mice receiving liposomes containing LYNK or CRP had significantly fewer and smaller liver metastases (25%-28%), than those in the two control groups (53%-54%). Also, a significantly better survival was noted in the two treated groups than in the two control groups. The most likely mechanism of tumor inhibition appears to be through macrophage activation. In the Winn tumor neutralization test, peritoneal macrophages harvested from normal mice 24 h after a single injection of liposomes (2.5 mumol) containing LYNK or CRP markedly inhibited tumor growth when a mixture of effector-target cells (40 : 1) was injected in the footpad. These studies further confirm the suggested role of CRP as an 'immunomodulator' or 'biological response modifier' in yet another tumor system.     

Possible Role of Arginase-1 in Concomitant Tumor Immunity

The expression of Adenovirus serotype 2 or serotype 5 (Ad2/5) E1A in tumor cells reduces their tumorigenicity in vivo by enhancing the NK cell mediated and T cell mediated anti-tumor immune response, an activity that correlates with the ability of E1A to bind p300. We determined if E1A could be used as a molecular adjuvant to enhance antigen-specific T cell responses to a model tumor antigen, ovalbumin (OVA). To achieve this goal, we stably expressed a fusion protein of E1A and OVA (MCA-205-E1A-OVA), OVA (MCA-205-OVA) or a mutant version of E1A unable to bind p300 and OVA (E1A-Δp300-OVA) in the B6-derived, highly tumorigenic MCA-205 tumor cell line. MCA-205-E1A-OVA tumor cells were over 10,000 fold less tumorigenic than MCA-205-OVA, MCA-205-E1A-Δp300-OVA, or MCA-205 in B6 mice. However, immunization of B6 mice with live MCA-205-OVA, MCA-205-E1A-Δp300-OVA and MCA-E1A-OVA tumor cells induced nearly equivalent OVA-specific CD4 T cells and CD8 CTL responses. Further studies revealed that mice with primary, enlarging MCA-205-OVA or MCA-205-E1A-Δp300-OVA tumors on one flank exhibited OVA-specific anti-tumor T cell responses that rejected a tumorigenic dose of MCA-205-OVA cells on the contralateral flank (concomitant tumor immunity). Next we found that tumor associated macrophages (TAMs) in progressive MCA-205-OVA tumors, but not MCA-205-E1A-OVA tumors that expressed high levels of arginase-1, which is known to have local immunosuppressive activities. In summary, immunization of mice with MCA-205 cells expressing OVA, E1A-Δp300-OVA or E1A-OVA induced equivalent OVA-specific CD4 and CD8 anti-tumor responses. TAMs found in MCA-205-OVA, but not MCA-205-E1A-OVA, tumors expressed high levels of arginase-1. We hypothesize that the production of arginase-1 by TAMs in MCA-205-OVA or MCA-205-E1A-Δp300-OVA tumor cells leads to an ineffective anti-tumor immune response in the tumor microenvironment, but does not result in inhibition of a systemic anti-tumor immunity.     

Analysis of reactive carbonyls in the expired air of transgenic mice.

Methods for the determination of trace levels of volatile carbonyl compounds in air expired from mice were developed and validated. Tumor bearing transgenic mice or nontransgenic control mice were placed into a glass chamber through which air was passed continuously at 90 ml/min for 1 h. The effluent gas stream was bubbled into an aqueous cysteamine solution or an aqueous methylhydrazine solution. Formaldehyde, acetaldehyde, and acetone in expired air were derivatized to thiazolidine with cysteamine and malonaldehyde was derivatized to 1-methyl-2-pyrazole with methylhydrazine. The derivatized compounds were analyzed by capillary gas chromatography with flame photometric or nitrogen-phosphorous-specific detection. The lowest level quantitated was 4 micrograms/ml thiazolidine, equivalent to 1.35 micrograms/ml formaldehyde. Formaldehyde was recovered at a level of 1356 +/- 234 nmol/kg0.75 (mean +/- SD) from mice with tumors and 898 +/- 97 nmol/kg0.75 from mice without tumors, suggesting that tumor bearing transgenic mice expired significantly more formaldehyde than did tumor free controls. Amounts of expired acetaldehyde and acetone were not different among mice. Malonaldehyde was not detected in either group of mice.     

Pharmacodynamic and protective properties of a murine lipopolysaccharide-specific monoclonal antibody in experimental Pseudomonas aeruginosa pneumonia in mice.

We employed a Pseudomonas aeruginosa mouse pneumonia model to evaluate the ability of a murine monoclonal antibody (MAb) specific for the O-side chain of P. aeruginosa Fisher Immunotype-1 lipopolysaccharide (LPS) to achieve and sustain therapeutic levels in plasma and lung tissue, reduce bacterial populations in the lung, and prevent pneumonia-associated mortality. An IgG3 MAb (Y1-5A4) administered to mice i.v. over a dose range of 125-1,000 micrograms/mouse produced plasma and lung tissue levels at 2 hr of 61-507 micrograms/ml and 4.3-150 micrograms/g, respectively. The 1,000 micrograms MAb dose reduced bacterial counts in lung tissue (log10 cfu/g +/- S.D.) and blood (log10 cfu/ml +/- S.D.) 20 hr post-treatment (18 hr post-challenge) from 10.00 +/- 0.66 to 7.66 +/- 0.91 (P less than 0.01) and from 4.39 +/- 0.81 to less than 3.0, respectively. Administration of MAb to mice in doses of 125-500 micrograms 2 hr prior to a 3 x 50% lethal bacterial challenge produced significant protection against death, with a calculated 50% protective dose of 167 micrograms. Protection was noted following administration of 1,000 micrograms of MAb up to 6 hr after bacterial challenge (P less than 0.05, compared with untreated control). Histological examination of lung tissue from infected mice revealed less acute inflammation, necrosis, and hemorrhage in MAb-treated compared with untreated control animals and greater localization of Pseudomonas antigen within the phagocytic cells in alveolar space. These findings document the in vivo therapeutic efficacy of an LPS-specific IgG MAb in a murine model of acute P. aeruginosa pneumonia, based in part upon the achievability of effective MAb concentrations in plasma and lung tissue.     

Proteoglycan isolated from Phellinus linteus inhibits tumor growth through mechanisms leading to an activation of CD11c+CD8+ DC and type I helper T cell-dominant immune state

Dendritic cells (DC) are known to not only induce the activation of T cells, but are also associated with the polarization of T cells. This study investigated whether or not proteoglycan (PG) isolated from Phellinus linteus induces the phenotypic and functional maturation of CD11c+ DC in vitro and in vivo. PG was found to induce the phenotypic and functional maturation of bone marrow-derived DC via Toll-like receptors (TLR) 2 and 4 in vitro. Administration of PG in vivo strongly inhibited the MCA-102 tumor growth and increase in vivo. The ratio of CD8+ DC to CD8- DC increased, and PG enhanced IL-12 and IFN-gamma production, and expression of surface molecules including major histocompatibility complexes (MHC) classes I, MHC II, CD80, and CD86 in MCA-102-challenged mice. PG also caused a marked increase in the production of Th (helper T cells)-1 cytokine (IFN-gamma) and a decrease in the production of Th-2 cytokine (IL-4) by splenic cells and inguinal lymph node cells in MCA-102 tumor-bearing mice. Furthermore, PG stimulated the proliferation of CD4+ and CD8+ T cells. In addition, a combination of PG and tumor lysate-pulsed DC inhibited completely the growth of MCA-102 cells in tumor-bearing mice. These results indicate that the administration of PG inhibited the tumor growth through a mechanism leading to a Th-1 dominant immune state and the activation of CD11cCD8+ DC.     

POST-MITOTIC AGE OF MONONUCLEAR CELLS MIGRATING INTO TA-3(St) SOLID TUMORS

Subcutaneous transplantation of 5 × 10⁶ TA-3(St) mammary carcinoma cells into A/J mice produced rapidly growing tumors that showed a substantial accumulation of lymphocytes, monocytes and macrophages. This must have resulted primarily from an influx of circulating cells, since none of the cell types exhibited any significant local proliferation as indicated by 1 hr ³H-TdR uptake. The post mitotic age of the various leukocyte types in circulation of normal and tumor bearing animals, and those appearing within the tumors, was evaluated by a repeated ³H-TdR labeling protocol designed to label newly formed leukocytes. Tumor transplantation (or injection of an equivalent volume of saline in control animals) was preceded by thirteen ³H-TdR injections (12.5 μCi every 8 hr) and followed by eight more injections at equivalent intervals. Animals were serially sacrificed at 5-14 days after tumor transplantation or saline injection. Total lymphocyte labeling in the blood during these intervals was higher in tumor bearing mice (approximately 25% between 5 and 12 days) than in the saline injected controls (approximately 20%), indicating that tumor transplantation resulted in an increase in the proportion of young lymphocytes in circulation. More significantly, a much higher labeling (57-60% at 5-12 days) was exhibited by lymphocytes isolated from the tumors, indicating selective migration (and/or retention) of newly formed lymphocytes within the tumor. This finding applied to lymphocytes in all size categories. Although blood monocyte labeling in the control and experimental animals was similar (e.g. 83% at day 5 and 52% at day 14), significantly higher labeling (e.g. 93% and 70% at the respective intervals) was exhibited by monocytes isolated from tumors. This suggested a preferential accumulation of young monocytes at the tumor site. An identical macrophage labeling pattern compared to that shown by monocytes within the tumor indicated a rapid monocyte-macrophage transition. Since these findings in the present strain-specific solid tumor are similar to those previously obtained in this laboratory in the strain-nonspecific Ehrlich ascites tumor, the phenomenon of selective localization of newly formed mono-nuclear leukocytes appears to be a general occurrence in transplanted murine tumors.     

Pituitary hypoplasia in Pttg-/- mice is protective for Rb+/- pituitary tumorigenesis

Pituitary tumor transforming gene (Pttg) is induced in pituitary tumors and associated with increased tumor invasiveness. Pttg-null mice do not develop tumors, but exhibit pituitary hypoplasia, whereas mice heterozygous for the retinoblastoma (Rb) deletion develop pituitary tumors with high penetrance. Pttg-null mice were therefore cross-bred with Rb+/- mice to test the impact of pituitary hypoplasia on tumor development. Before tumor development, Rb+/-Pttg-/- mice have smaller pituitary glands with fewer cycling pituitary cells and exhibit induction of pituitary p21 levels. Pttg silencing in vitro with specific short hairpin interfering RNA in AtT20 mouse corticotrophs led to a marked induction of p21 mRNA and protein levels, decreased RB phosphorylation, and subsequent 24% decrease in S-phase cells. Eighty-six percent of Rb+/-Pttg+/+ mice develop pituitary adenomas by 13 months, in contrast to 30% of double-crossed Rb+/-Pttg-/- animals (P < 0.01). Pituitary hypoplasia, associated with suppressed cell proliferation, prevents the high penetrance of pituitary tumors in Rb+/- animals, and is therefore a protective determinant for pituitary tumorigenesis.     

Validation and Comparison of the Therapeutic Efficacy of Boron Neutron Capture Therapy Mediated By Boron-Rich Liposomes in Multiple Murine Tumor Models

Boron neutron capture therapy (BNCT) was performed at the University of Missouri Research Reactor in mice bearing CT26 colon carcinoma flank tumors and the results were compared with previously performed studies with mice bearing EMT6 breast cancer flank tumors. Mice were implanted with CT26 tumors subcutaneously in the caudal flank and were given two separate tail vein injections of unilamellar liposomes composed of cholesterol, 1,2-distearoyl-sn-glycer-3-phosphocholine, and K[nido-7-CH₃(CH₂)₁₅–7,8-C₂B₉H₁₁] in the lipid bilayer and encapsulated Na₃[1-(2`-B₁₀H₉)-2-NH₃B₁₀H₈] within the liposomal core. Mice were irradiated 30 hours after the second injection in a thermal neutron beam for various lengths of time. The tumor size was monitored daily for 72 days. Despite relatively lower tumor boron concentrations, as compared to EMT6 tumors, a 45 minute neutron irradiation BNCT resulted in complete resolution of the tumors in 50% of treated mice, 50% of which never recurred. Median time to tumor volume tripling was 38 days in BNCT treated mice, 17 days in neutron-irradiated mice given no boron compounds, and 4 days in untreated controls. Tumor response in mice with CT26 colon carcinoma was markedly more pronounced than in previous reports of mice with EMT6 tumors, a difference which increased with dose. The slope of the dose response curve of CT26 colon carcinoma tumors is 1.05 times tumor growth delay per Gy compared to 0.09 times tumor growth delay per Gy for EMT6 tumors, indicating that inherent radiosensitivity of tumors plays a role in boron neutron capture therapy and should be considered in the development of clinical applications of BNCT in animals and man.