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Amanda Pennington,Vasyl Sava,Shijie Song,Niketa Patel,Sanchez-Ramos
Introduction: Granulocyte colony stimulating factor (G-CSF) administration produces beneficial effects in rodent models of stroke, trauma and neurodegenerative diseases by acting on both bone marrow-derived and neuronal cells. The aim of the study was to elucidate cellular mechanism(s) of G-CSF action by direct application to neuronal and monocytic cell lines.
Method: Cell culture models of monocytes (THP-1) and neurons (SH-SY5Y) cells were incubated with G-CSF. The following parameters were measured: G-CSF receptor binding kinetics; DNA synthesis; signal transduction, in particular expression of alternatively spliced protein kinase C (PKCδVIII) and the anti-apoptotic protein Bcl-2; changes in adhesiveness and migratory properties induced by G-CSF in the monocytic cells.
Results: G-CSF receptor binding kinetics in the two lines differed, with Kd in the neuronal line being significantly higher than that of the monocytic cells. Despite higher affinity of G-CSF for receptors on the monocytic cells, G-CSF treatment increased Bcl-2 expression in the neuronal line at lower concentrations than that required in the monocytic cell line. G-CSF did not increase either cellular adhesiveness or migration through a semi-permeable membrane, whereas monocyte chemotactic protein (MCP-1) significantly improved migration.
Conclusions: The cellular and molecular responses to G-CSF treatment of monocytic cells suggest that neither changes in adhesiveness nor migratory capacity are responsible for the beneficial effects of G-CSF administration in models of neurologic diseases. G-CSF induction of anti-apoptotic signaling in neurons is an important component of its neuroprotective effects in models of brain injury.