A human monoclonal IgG1 potently neutralizing the pro-inflammatory cytokine GM-CSF.

The pro-inflammatory cytokine GM-CSF is aberrantly produced in many autoimmune and chronic inflammatory human diseases. GM-CSF neutralization by antibodies has been shown to have a profound therapeutic effect in animal models of rheumatoid arthritis, inflammatory lung diseases, psoriasis and multiple sclerosis. Moreover, the absence of GM-CSF in null mutant mice ameliorates or prevents certain of these diseases. Here we describe the biophysical and biological properties of a human anti-GM-CSF IgG1 antibody designated MT203, which was derived by phage display guided selection. MT203 bound with picomolar affinity to an epitope on human and macaque GM-CSF involved in high-affinity receptor interaction. As a consequence, the antibody potently prevented both GM-CSF-induced proliferation of TF-1 cells with a sub-nanomolar IC50 value and the production of the chemokine IL-8 by U937 cells. MT203 neutralized equally well recombinant (r) human (h) GM-CSF from Escherichia coli and yeast, and also normally glycosylated GM-CSF secreted by human lung epithelial cells in response to IL-1beta stimulation. Furthermore, MT203 significantly reduced both survival and activation of peripheral human eosinophils as may be required for effective treatment of inflammatory lung diseases. The antibody did not show a detectable loss of neutralizing activity after 5 days in human serum at 37 degrees C. Based on its favorable properties, MT203 has been selected for development as a novel anti-inflammatory human monoclonal antibody with therapeutic potential in a multitude of human autoimmune and inflammatory diseases.

A highly stable polyethylene glycol-conjugated human single-chain antibody neutralizing granulocyte-macrophage colony stimulating factor at low nanomolar concentration.

GM-CSF (granulocyte-macrophage colony stimulating factor) plays a central role in inflammatory processes. Treatment with antibodies neutralizing murine GM-CSF showed significant therapeutic effects in mouse models of inflammatory diseases. We constructed by phage display technology a human scFv, which could potently neutralize human GM-CSF. At first, a human V(L) repertoire was combined with the V(H) domain of a parental GM-CSF-neutralizing rat antibody. One dominant rat/human scFv clone was selected, neutralizing human GM-CSF with an IC50 of 7.3 nM. The human V(L) of this clone was then combined with a human V(H) repertoire. The latter preserved the CDR 3 of the parental rat V(H) domain to retain binding specificity. Several human scFvs were selected, which neutralized human GM-CSF at low nanomolar concentrations (IC50 > or = 2.6 nM). To increase serum half-life, a branched 40 kDa PEG-polymer was coupled to the most potent GM-CSF-neutralizing scFv (3077) via an additional C-terminal cysteine. PEG conjugation had a negligible effect on the in vitro neutralizing potential of the scFv, although it caused a significant drop in binding affinity owing to a reduced on-rate. It also significantly increased the stability of the scFv at elevated temperatures. In mouse experiments, the PEGylated scFv 3077 showed a significantly prolonged elimination half-life of 59 h as compared with 2 h for the unconjugated scFv version. PEGylated scFv 3077 is a potential candidate for development of a novel antibody therapy to treat pro-inflammatory human diseases.