To define activity-dependent release of endogenous brainderived neurotrophic factor (BDNF), we developed an in vitro model using primary sensory neurons and a modified ELISA, termed ELISA in situ. Dissociate cultures of nodose-petrosal ganglion cells from newborn rats were grown in wells precoated with anti-BDNF antibody to capture released BDNF, which was subsequently detected using conventional ELISA. Conventional ELISA alone was unable to detect any increase in BDNF concentration above control values following chronic depolarization with 40 mM KCl for 72 hr. However, ELISA in situ demonstrated a highly significant increase in BDNF release, from 65 pg/ml in control to 228 pg/ml in KCl-treated cultures. The efficacy of the in situ assay appears to be related primarily to rapid capture of released BDNF that prevents BDNF binding to the cultured cells. We therefore used this approach to compare BDNF release from cultures exposed for 30 min to either continuous depolarization with elevated KCl or patterned electrical field stimulation (50 biphasic rectangular pulses of 25 msec, at 20 Hz, every 5 sec). Short-term KCl depolarization was completely ineffective at evoking any detectable release of BDNF, whereas patterned electrical stimulation increased extracellular BDNF levels by 20-fold. In addition, the magnitude of BDNF release was dependent on stimulus pattern, with high-frequency bursts being most effective. These data indicate that the optimal stimulus profile for BDNF release resembles that of other neuroactive peptides.Moreover, our findings demonstrate that BDNF release can encode temporal features of presynaptic neuronal activity.
Key words: BDNF release; chronic depolarization; electrical field stimulation; ELISA; ELISA in situ; frequency; patterned stimulation; P-CREB; primary sensory neuronsThere is increasing evidence that brain-derived neurotrophic factor (BDNF) plays a trans-synaptic role in regulating transmission between primary sensory neurons and second-order sensory relay cells. BDNF is expressed by subsets of sensory ganglion cells (Schecterson and Bothwell, 1992;Wetmore and Olson, 1995;Apfel et al., 1996;Zhou et al., 1998;Brady et al., 1999), can be transported in the central projections of dorsal root ganglion (DRG) neurons (Zhou and Rush, 1996;Tonra, 1999), and is localized to dense-core vesicles within DRG central axon terminals (Michael et al., 1997). Our studies demonstrated that survival of sensory neurons that both express and depend on BDNF can be supported by long-term exposure to elevated potassium, indicating that BDNF can be released under depolarizing conditions in culture (Brady et al., 1999). More recently we found that BDNF acutely inhibits AMPA-mediated currents in second-order sensory relay neurons, indicating that BDNF may modulate glutamatergic primary afferent transmission (Balkowiec et al., 2000). In addition, Kerr et al. (1999) demonstrated that BDNF can potentiate nociceptive spinal reflexes by enhancing NMDA receptor-mediated responses. Despite these findings, little i...
