We have investigated the ability of recombinant TNF (mouse and human) to produce acute inflammatory lesions in an established experimental model of inflammation. Upon intradermal injection in rabbit skin, TNF, in amounts as low as 3 x 10(-14) mol/site, was found to be very potent at inducing local neutrophil accumulation and neutrophil-dependent oedema formation, thereby fulfilling two important criteria to be considered as an inflammatory mediator. Our findings further indicate that the pro-inflammatory properties of TNF are probably more related to its immediate stimulatory effects on neutrophils rather than to its slow (protein biosynthesis-dependent effects on endothelial cells. Our data thus show that very low amounts of mouse and human recombinant TNF can initiate an acute inflammatory reaction in vivo in rabbit skin and that TNF is able to evoke two of the four cardinal signs of inflammation.
The pro-inflammatory properties of IL 1 and TNF were investigated in an in vivo model of inflammation. IL 1 induced PMN leukocyte accumulation that was slow in onset, reaching a peak rate at 3-4 h and that was inhibitable by Actinomycin D and Cycloheximide. PMN leukocyte emigration was not associated with any significant plasma leakage. In contrast, TNF induced PMN leukocyte accumulation and oedema formation, that were rapid in onset and very short of duration (t1/2 6-10 min). TNF-induced plasma leakage was PMN leukocyte-, but not protein biosynthesis-dependent. The differences in time course and biological profile suggest that IL 1 and TNF exert their pro-inflammatory effects in vivo via different mechanisms.
Several monoclonal antibodies (mAb) against rabbit leukocytes were characterized in binding and functional studies. mAb 1.24 stains thymocytes, bone marrow cells, peripheral T and B cells and blood monocytes. T cells express more 1.24 antigen than B cells. In the absence of added complement (C), mAb 1.24 inhibits alloantigen-, concanavalin A (Con A)-, and phytohemagglutinin (PHA)-, but not pokeweed mitogen (PWM)- or anti-immunoglobulin (Ig)-induced cell proliferation. It also strongly blocks anti-sheep erythrocyte plaque-forming cell responses. A second mAb, designated 4.B9, binds to 20% of thymocytes and to most, if not all, peripheral T cells and in vitro-activated T cell blasts. A third one, 10.B3, is reactive with the nearly entire thymocyte and a major peripheral T cell population. Two-color membrane immunofluorescence reveals the presence of a small population of peripheral blood leukocytes which bear surface Ig and are weakly stained by mAb 4.B9 and 10.B3. Without C, both 4.B9 and 10.B3 inhibit Con A- and PHA-induced mitogenesis, but have no effect on PWM-, antigen-, or alloantigen-induced cell proliferation. Depletion of 4.B9+ cells by panning or complement lysis completely abrogates proliferative responsiveness to antigen and alloantigen, significantly reduces responsiveness to the T cell mitogens Con A and PHA, but enhances that to the B cell mitogen anti-Ig. A fourth mAb, 12.C7, binds to 60% of thymocytes and to 10-30% of peripheral T lymphocytes at high-level fluorescence. T cell blasts obtained in mixed leukocyte reactions are partially stained by mAb 12.C7, while those obtained after Con A or PHA activation are not. In addition, mAb 12.C7 is completely unreactive with B cells or monocytes. Without complement, it does not seem to interfere with any of the in vitro functions tested. All antigens studied here do not appear to be expressed in nonleukon tissues, as they do not bind to erythrocytes and are absent from brain, heart, liver and kidney as shown by quantitative absorption analysis.
Peripheral blood leukocytes (PBL) from primed rabbits were able to suppress the in vitro anti-sheep red blood cell (SRBC) plaque-forming cell (PFC) response of autologous spleen cells. A population containing the suppressor cells could be isolated from PBL by cell fractionation on columns of insolubilized histamine. In contrast to spleen cells, PBL generatd a weak secondary anti-SRBC response in vitro. A strong response was obtained with PBL freed from histamine-binding (H+) cells. The addition of these H+ cells to cultures of H-PBL caused strong suppression. The H+ suppressor cell was further characterized as a radioresistant T cell. Low-dose irradiation of H- cells resulted in a supplementary enhanced PFC response suggesting that PBL also contain a radiosensitive regulator cell which is not histamine binding.
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