Agnes Fütterer

A monocytic cell line, termed Mono Mac, was established from peripheral blood of a patient with monoblastic leukemia. Two clones, designated Mono Mac I and Mono Mac 6, were isolated and both were assigned to the monocyte lineage on the basis of morphological, cytochemical and immunological criteria. Most importantly, the clones express NaF-sensitive non-specific-esterase, produce reactive oxygen and stain with MAb My4. Mono Mac 6, in addition, constitutively exhibits phagocytosis of antibody-coated erythrocytes in 80% of the cells and reacts with a panel of MAbs that are specific for mature monocytes, i.e., M42, LeuM3, 63D3, Mo2 and UCHMI. By contrast, the monoblastic cell lines U937 and THP-I are negative for all these markers. Only expression of My4 could be detected after differentiation induced by interferon-gamma (IFN-gamma). Similar treatment of Mono Mac I, however, resulted in staining with all the monocyte-specific MAbs mentioned above, while IFN-gamma treatment of Mono Mac 6 enhanced antigen expression. In addition, the cells showed an increased frequency of multinucleated cells with a rise from 4.8% to 21.9%. Mono Mac 6 appears to be the only one of the cell lines studied to constitutively express phenotypic and functional features of mature monocytes.

The formation of germinal centers (GCs) represents a crucial step in the humoral immune response. Recent studies using gene-targeted mice have revealed that the cytokines tumor necrosis factor (TNF), lymphotoxin (LT) alpha, and LTbeta, as well as their receptors TNF receptor p55 (TNFRp55) and LTbetaR play essential roles in the development of GCs. To establish in which cell types expression of LTbetaR, LTbeta, and TNF is required for GC formation, LTbetaR-/-, LTbeta-/-, TNF-/-, B cell-deficient (BCR-/-), and wild-type mice were used to generate reciprocal or mixed bone marrow (BM) chimeric mice. GCs, herein defined as peanut agglutinin-binding (PNA+) clusters of centroblasts/centrocytes in association with follicular dendritic cell (FDC) networks, were not detectable in LTbetaR-/- hosts after transfer of wild-type BM. In contrast, the GC reaction was restored in LTbeta-/- hosts reconstituted with either wild-type or LTbetaR-/- BM. In BCR-/- recipients reconstituted with compound LTbeta-/-/BCR-/- or TNF-/-/BCR-/- BM grafts, PNA+ cell clusters formed in splenic follicles, but associated FDC networks were strongly reduced or absent. Thus, development of splenic FDC networks depends on expression of LTbeta and TNF by B lymphocytes and LTbetaR by radioresistant stromal cells.

IFN-gamma induces a number of cellular programs functional in innate and adaptive resistance to infectious pathogens. It has recently become clear that the complete cellular response to IFN-gamma is extraordinarily complex, with >500 genes (i.e., approximately 0.5% of the genome) activated. We made suppression-subtractive hybridization differential libraries from IFN-gamma-stimulated primary mouse embryonic fibroblasts and from a mouse macrophage cell line, ANA-1, in each case with reference to unstimulated cells. Of approximately 250 clones sequenced at random from the two libraries, >35% were representatives of one or the other of two small unrelated families of GTPases, the 65-kDa and 47-kDa families. These families dominate the IFN-gamma-induced response in both cell types. We report here the full-length sequences of one new 65-kDa and two new 47-kDa family members. The 65-kDa family members are under transcriptional control of IRF-1, whereas the 47-kDa family members are inducible in embryonic fibroblasts from IRF-1(-/-) mice. Members of both GTPase families are strongly up-regulated in livers of wild-type mice infected with the pathogenic bacterium, Listeria monocytogenes, but not in IFN-gammaR(0/0) mice. These GTPases appear to be dedicated to the IFN-gamma response, since resting levels are negligible and since neither family shows any significant relationship to any other described family of GTPases. Understanding the role of these GTPases in IFN-gamma-mediated resistance against pathogens is the task for the future.

Abstract IFN-γ induces a number of cellular programs functional in innate and adaptive resistance to infectious pathogens. It has recently become clear that the complete cellular response to IFN-γ is extraordinarily complex, with >500 genes (i.e., ∼0.5% of the genome) activated. We made suppression-subtractive hybridization differential libraries from IFN-γ-stimulated primary mouse embryonic fibroblasts and from a mouse macrophage cell line, ANA-1, in each case with reference to unstimulated cells. Of ∼250 clones sequenced at random from the two libraries, >35% were representatives of one or the other of two small unrelated families of GTPases, the 65-kDa and 47-kDa families. These families dominate the IFN-γ-induced response in both cell types. We report here the full-length sequences of one new 65-kDa and two new 47-kDa family members. The 65-kDa family members are under transcriptional control of IRF-1, whereas the 47-kDa family members are inducible in embryonic fibroblasts from IRF-1−/− mice. Members of both GTPase families are strongly up-regulated in livers of wild-type mice infected with the pathogenic bacterium, Listeria monocytogenes, but not in IFN-γR0/0 mice. These GTPases appear to be dedicated to the IFN-γ response, since resting levels are negligible and since neither family shows any significant relationship to any other described family of GTPases. Understanding the role of these GTPases in IFN-γ-mediated resistance against pathogens is the task for the future.