Nociceptors belong to Ad and C afferents that are equipped in the periphery with receptors for detecting potentially damaging physical and chemical stimuli. This review summarizes experimental evidence that these receptors represented by ionic channels are also functionally expressed on the cell bodies of sensory neurones in short-term cultures. The nociceptors belong predominantly to the small and medium size DRG neurones in which algogens such as weak acids, capsaicin, bradykinin and serotonin produce inward currents that can generate impulse activity. It seems likely that the neurones which are not sensitive to algogens but to GABA, ATP or glutamate, agents not producing pain in humans, belong to other categories of DRG neurones equipped for detecting other modalities of sensation. New techniques for physical stimulation of DRG neurones in culture may be of great help in the search for complementing the criteria for distinguishing nociceptors among other neurones in culture. It is suggested that such an in vitro model will be useful for studying cellular mechanisms of nociception.
Membrane currents induced by capsaicin (CAPS) in cultured sensory neurons from 1- to 2-day-old rats were studied. Responses to CAPS (lO^M) exceeding 1 nA at -50 mV were found in smaller, usually bipolar or tripolar neurons in which GABA (30 yuM) induced small or no response. Large, unipolar neurons, which exhibited large responses to GABA, were completely insensitive to CAPS (10//M). In contrast to GABA, responses to CAPS exhibited a slow rise and slow decay and a marked tachyphylaxis after repeated CAPS applications at high concentrations which made it difficult to study the concentration-response relationship. In partially run-down neurons, which exhibited quasi stable responses, the slope of the ascending phase was concentration-dependent with an apparent association rate constant Ki 9x104 [M-1s-1]. The time constant of the decay was 3.5 s, and was concentration-independent. However, in 5 neurones the EC50 measured from the first series of CAPS applications at increasing concentrations was 0.31 ±0.5ptA with a Hill coefficient 1.66±0.35. The responses to CAPS reversed at +10.4±2.5 mV suggesting that the current is carried nonselectively by monovalent cations and Ca2+. The channel conductance of CAPS-gated channels at -50 mV calculated from the mean membrane current and variance of the current noise in outside-out patches or measured directly was 28 pS (n=5). It is suggested that the CAPS-gated channels are either controlled by receptors with a very high affinity or that the channels are controlled by membrane-bound protein(s) which do not depend in their function on the supply of GTP or other intracellular metabolites.