Colchicine down-regulates lipopolysaccharide-induced granulocyte-macrophage colony-stimulating factor production in murine macrophages.

Activation of macrophages by LPS and taxol results in production of IL-1, IL-6, TNF-alpha, and granulocyte-macrophage CSF (GM-CSF), which are involved in regulating hemopoiesis, inflammation, and immune responses. Microtubules are proposed as a target site for LPS interaction(s), based on similarities between the effects of the tubulin-binding drug taxol and LPS. To clarify the role of microtubules in LPS-induced GM-CSF expression in macrophages, we examined whether microtubule depolymerizing agents affect GM-CSF production in macrophages. Pretreatment with colchicine impaired LPS induction of GM-CSF in RAW 264 cells, and studies using stable transfectants revealed that colchicine impaired the transcriptional responsiveness of a reporter gene driven by a GM-CSF promoter sequence. Colchicine inhibition of the GM-CSF response correlated with decreases in the mRNA levels of beta-tubulin; maximal inhibition of both events was observed 4 h after addition of colchicine. Microtubule agents inhibited LPS induction of IL-6 and TNF-alpha, while the induction of both IL-1beta and inducible nitric oxide synthase was unaltered, suggesting that LPS activates microtubule-dependent and -independent pathways. Interestingly, LPS stimulation of macrophages down-regulated levels of beta-tubulin transcripts, implying that LPS interacts with an element(s) of the microtubule network in vivo, activating pathways regulating transcription of beta-tubulin. The ability of both colchicine and LPS to modulate transcription of beta-tubulin suggests that this event does not per se underlie the inhibitory effect of colchicine on LPS-induced GM-CSF expression. These data led us to conclude that colchicine inhibits LPS induction of GM-CSF by affecting microtubule-dependent costimulatory signaling pathways that synergize with primary LPS-triggered responses.

Expression of human glucocerebrosidase in murine macrophages: identification of efficient retroviral vectors.

Gaucher's disease is an autosomal recessive disorder characterized by a functional deficiency in beta-glucocerebrosidase enzymatic activity and the resultant accumulation of the glycolipid glucocerebroside in macrophages. Due to the nature of the affected cells, Gaucher's disease is an excellent candidate for gene therapy of hematopoietic stem cells and autologous bone marrow transplantation of transduced cells using retroviral vectors containing the glucocerebrosidase (GC) gene. In order to identify a retroviral vector capable of high levels of expression of the GC gene in macrophages, we have used the murine myeloid leukemia cell line, M1, a cell line that can be differentiated with interleukin-6 (IL-6) from blasts to macrophages. Two vectors use the Moloney murine leukemia virus (MoMLV) enhancer/promoter (LG vector) or the myeloproliferative sarcoma virus (MPSV) enhancer/MoMLV promoter (MG vector), both located in the viral long-terminal repeat (LTR); the third vector uses the phosphoglycerate kinase (PGK) promoter located internally in the vector (PG vector). The amphotropic PA317 and GP+am12 packaging cell lines were used as virus producer cells, and the GP+am12 cell line demonstrated higher titers, higher levels of GC protein expression, and specific GC enzymatic activity as well as higher transduction efficiencies for all three vectors. The LG retroviral vector was the most efficient in transducing the M1 cells. On average, higher levels of RNA and protein expression were seen in the M1 clones transduced with the LG vector, and these levels increased after differentiation. Thus, the LG retroviral vector in which the expression of the GC gene is driven by the MoMLV LTR enhancer/promoter is the best vector of the three studied for future studies for gene therapy of Gaucher's disease and other hematopoietic disorders that involve macrophages.

Evaluation of expression of transferred genes in differentiating myeloid cells: expression of human glucocerebrosidase in murine macrophages.

The retroviral vector LGSN, in which the human glucocerebrosidase (GC) cDNA is driven by the Moloney murine leukemia virus (MoMLV) long terminal repeat (LTR), was tested for expression in the murine myelomonocytic leukemia cell line M1 before and after induction of differentiation with interleukin-6 (IL-6). Southern analysis of the seven transduced clones selected for neomycin resistance in Geneticin (G-418 sulfate) demonstrated one to eight copies of intact provirus with rearrangements in only two clones. Absolute levels of human GC RNA and protein increased with increased copy numbers of provirus in the clones. Upon induction with IL-6 of the seven transduced clones to the macrophage phenotype, there was no significant change, overall, in RNA levels but some increase in human GC protein levels could be detected. Although this was the average trend, considerable clonal variation in RNA and protein levels was observed upon induction. Transduction of the M1 cells did not interfere with the ability of the cells to differentiate from blasts to macrophages as seen by the appearance of membrane receptors for the constant region of immunoglobulins (Fc gamma RI) and lysozyme production in the differentiated M1 cells. Thus, the M1 cell line can be used for testing retroviral vector expression in myeloid lineages at early and late stages of differentiation. This rapid in vitro testing of potential retroviral vectors will be beneficial for gene therapy of disorders that affect differentiated macrophages such as Gaucher's disease.

Antagonistic and agonistic effects of transforming growth factor-beta and IL-1 in rheumatoid synovium.

We investigated potential mechanisms by which lymphocytes infiltrating rheumatoid synovium become immunosuppressed. In 20 of 22 synovial fluids and 12 of 13 synovial tissue culture supernatants, no IL-1 bioactivity could be detected in the thymocyte proliferation assay. These same preparations could, however, support proliferation of fibroblast monolayers, consistent with the presence of IL-1 and/or other fibroblast growth factors. Addition of either rheumatoid synovial fluids or synovial culture supernatants to exogenous IL-1 in the IL-1 bioassay caused marked inhibition of the assay indicative of an IL-1 inhibitor. This inhibition of IL-1 could be reversed by treating the effusions or supernatants with a neutralizing antibody to transforming growth factor-beta (TGF-beta). Furthermore, monocyte-macrophages isolated from rheumatoid synovial fluid constitutively released both latent and active TGF-beta in culture at levels sufficient to completely block the biologic activity of 100 U/ml IL-1. The production of substantial levels of TGF-beta by synovial macrophages, as well as the apparent ability of these inflammatory macrophages to activate latent TGF-beta, implicates TGF-beta not only as an important inhibitor of IL-1-induced lymphocyte proliferation, but also as a key cytokine in promoting synovial fibroblast hyperplasia and pathology.

Capacity of human large granular lymphocytes (LGL) to produce multiple lymphokines: interleukin 2, interferon, and colony stimulating factor.

Human large granular lymphocytes (LGL), which are known to be responsible for natural killer (NK) cell activity, also produced a variety of lymphokines including interleukin 2 (IL 2), colony stimulating factor (CSF), and interferon (IFN) in response to phytohemagglutinin (PHA) or concanavalin A (Con A). Human peripheral blood LGL, which were purified by removal of monocytes adhering to plastic flasks and nylon columns, followed by separation on a discontinuous Percoll gradient, and additional treatment with anti-OKT3 and Leu-M1 plus complement, were more potent producers of these lymphokines than unseparated mononuclear cells (MNC), nylon column-eluted cells, or purified T lymphocytes. Moreover, IL 2 production by LGL could be further distinguished in that it was not enhanced by the addition of macrophages or macrophage-derived factor, i.e., IL 1, whereas addition of macrophages did potentiate IL 2 production by T lymphocytes. Further analysis of cells in the LGL population using various monoclonal antibodies revealed that removal of cells with OKT11 or AF-10, a monoclonal antibody against human HLA-DR antigen, decreased IL 2 production, whereas removal of OKT8+, OKM1+, Leu-M1+, or Leu-7+ cells led to enhanced IL 2 production. The LGL population is therefore heterogeneous and includes at least three functionally and phenotypically distinct subsets. An atypical T cell subset (OKT3-, Leu-1-, OKT11+) rather than the myeloid subset of LGL (Leu-M1+ or OKMI+) was the source of LGL-derived IL 2, whereas the latter subset and/or another subset of OKT8+ cells appear to regulate this IL 2 production. In addition to performing NK activity, LGL on a per cell basis seem to be more effective than T lymphocytes in producing lymphokines, namely, IL2, CSF, and IFN.

Interleukin 2-mediated immune interferon (IFN-gamma) production by human T cells and T cell subsets.

Human interleukin 2 (IL 2, or T cell growth factor), which was free of lectin and interferon activity (IFN), induced human peripheral T lymphocytes to produce immune IFN (IFN-gamma). In contrast, non-T cells and macrophages did not produce IFN-gamma in response to IL 2. IL 2 acted directly on unstimulated T cells to induce IFN-gamma production, and also acted in synergy with a suboptimal dose (2 micrograms/ml) of concanavalin A (Con A) to enhance IFN-gamma production. The IFN-gamma-inducing activity of partially purified IL 2 was absorbed along with the IL 2 activity by murine IL 2-dependent CT-6 cell line cells. This further supports the view that IFN-gamma-inducing activity is identical to IL 2. When T cells were separated further into helper/inducer T4+ and suppressor/cytotoxic T8+ subsets by negative selection with monoclonal antibody and complement, both T4+ and T8+-enriched cells produced significant levels of IFN-gamma in response to IL 2. Complete removal of macrophages from purified T lymphocyte populations by treatment of OKM1 plus complement consistently reduced IFN-gamma production in response to IL 2 to a limited degree; readdition of macrophages restored IFN-gamma production by both T cell subsets. This observation that IL 2 contributes to the production of IFN-gamma by human lymphocytes suggests that a cascade of lymphocyte-cell interactions participates in human immune responses.

Release of histamine from hamster mast cells by concanavalin A and phytohemagglutinin.

Concanavalin A (Con A) and phytohemagglutinin (PHA) released histamine from hamster mast cells incubated in a serum-free medium. Concentrations of Con A and PHA approximating those optimal for transforming lymphocytes also released maximal amounts of histamine without apparent cytotoxicity. Higher concentrations of mitogen inhibited both lymphocyte transformation and histamine release. Incubation at 37 C for 15 min released histamine, although longer times were more effective. Supernatants from cultured hamster splenocytes stimulated with Con A also released histamine from added mast cells. However, the effect could be inhibited by the addition of 0.1 M methyl alpha-D-mannoside or by passing the spleen cell culture supernatants through Sephadex G-75 to remove Con A. This mitogen-induced release of mast cell histamine is therefore not mediated by a lymphokine but probably results from a direct interaction of mitogens with receptors on mast cells.