Effects of ciliary neurotrophic factor on the survival and response to nerve growth factor of cultured rat sympathetic neurons.

The development and maturation of cells depends not only on their genetic history, but also on sequences and combinations of environmental signals appropriate to their developmental age. Early postnatal rat sympathetic neurons are dependent on nerve growth factor (NGF) for survival in vivo and in vitro, but earlier sympathetic neuroblasts may not require NGF. Ciliary neurotrophic factor (CNTF) provides short-term in vitro trophic support to embryonic and neonatal sympathetic neurons, but its role in vivo is not understood. In this study we examined further the capability of CNTF to support neonatal rat superior cervical ganglion (SCG) sympathetic neurons in vitro and the effect of CNTF on the trophic activities of NGF. SCG neurons cultured with either CNTF or NGF survived for 24 hr in low-density cultures depleted of nonneuronal cells, in contrast to neurons with neither factor. However, with CNTF only a fraction of the NGF-maintained number of neurons survived for 6 days. CNTF given in combination with NGF in these nonneuron-depleted cultures produced a significant decrease in the number of neurons surviving for 6 days, compared to the number supported by NGF alone. If such cultures were supplemented with Schwann cells, very different results were obtained: CNTF alone supported the 6-day survival of 80% as many neurons as did NGF, and the combination of CNTF with NGF produced no decrease in neuronal survival. Antibody to NGF did not block the support provided by CNTF and Schwann cells. Immunostaining for the low-affinity NGF receptor (LNGFR), intense in the NGF-supported neurons, was absent in the CNTF-supported neurons and reduced in the neurons exposed to the combination of NGF and CNTF. These results show that CNTF can act synergistically with a Schwann cell-derived agent to provide trophic support to neonatal sympathetic neurons, and that it can down-regulate the responsiveness of those neurons to NGF.