Warm cells revealed by microfluorimetry of Ca2+ in cultured dorsal root ganglion neurons

The immunosuppressant FK506 activates capsaicin- and bradykinin-sensitive DRG neurons and cutaneous C-fibers

Immunosuppressant drug FK506, which is widely used for the treatment of atopic dermatitis, has multiple actions on the nervous system. In order to elucidate the mechanisms underlying transient burning sensation elicited by topical application of FK506 to the skin of atopic patients, we investigated if FK506 directly activates sensory neurons and fibers, or not. Ca(2+) imaging study on cultured DRG neurons of rats revealed that application of FK506 raised intracellular Ca(2+) levels in a subpopulation of small DRG neurons (3.1% of DRG neurons responsive to high K(+) solution). When DRGs from inflamed rats were used, the incidence increased to 7.4%. FK506 sensitive neurons also responded to a subsequent application of capsaicin (89.5% in normal, and 100% in inflamed rats) and bradykinin (31.6% in normal, and 80.9% in inflamed rats). Single fiber recordings in the skin-nerve preparation confirmed the results of cell culture study, showing that application of FK506 enhanced neuronal discharges of single C-fibers that are responsive to heat and bradykinin. These findings, taken together, indicate that FK506 application on inflamed skin may activate nociceptive C-fibers, which bear bradykinin receptors and capsaicin-sensitive heat transducer of TRP family, TRPV1.

Thermosensitive transient receptor potential channels in vagal afferent neurons of the mouse

A number of transient receptor potential (TRP) channels has recently been shown to mediate cutaneous thermosensitivity. Sensitivity to warm and cool stimuli has been demonstrated in both human and animal gastrointestinal tract; however, the molecular mechanisms that underlie this have not been determined. Vagal afferent neurons with cell bodies in the nodose ganglion are known to mediate nonnociceptive sensation from the upper gut. In this study, isolated cultured nodose ganglion from the mouse neurons showed changes in cytoplasmic-free Ca(2+) concentrations over a range of temperatures, as well as to icilin (a TRPM8 and TRPN1 agonist) and capsaicin (a TRPV1 agonist). RT-PCR was used to show the presence of six temperature-sensitive TRP channel transcripts (TRPV1-4, TRPN1, and TRPM8) in whole nodose ganglia. In addition, RT-PCR of single nodose cell bodies, which had been retrogradely labeled from the upper gut, detected transcripts for TRPV1, TRPV2, TRPV4, TRPN1, and TRPM8 in a proportion of cells. Immunohistochemical labeling detected TRPV1 and TRPV2 proteins in nodose ganglia. The presence of TRP channel transcripts and proteins was also detected in cells within several regions of the gastrointestinal tract. Our results reveal that TRP channels are present in subsets of vagal afferent neurons that project to the stomach and may confer temperature sensitivity on these cells.

TRPV3 is a calcium-permeable temperature-sensitive cation channel

Transient receptor potential (TRP) proteins are cation-selective channels that function in processes as diverse as sensation and vasoregulation. Mammalian TRP channels that are gated by heat and capsaicin (>43 degrees C; TRPV1 (ref. 1)), noxious heat (>52 degrees C; TRPV2 (ref. 2)), and cooling (< 22 degrees C; TRPM8 (refs 3, 4)) have been cloned; however, little is known about the molecular determinants of temperature sensing in the range between approximately 22 degrees C and 40 degrees C. Here we have identified a member of the vanilloid channel family, human TRPV3 (hTRPV3) that is expressed in skin, tongue, dorsal root ganglion, trigeminal ganglion, spinal cord and brain. Increasing temperature from 22 degrees C to 40 degrees C in mammalian cells transfected with hTRPV3 elevated intracellular calcium by activating a nonselective cationic conductance. As in published recordings from sensory neurons, the current was steeply dependent on temperature, sensitized with repeated heating, and displayed a marked hysteresis on heating and cooling. On the basis of these properties, we propose that hTRPV3 is thermosensitive in the physiological range of temperatures between TRPM8 and TRPV1.

Changes in cytosolic calcium in response to noxious heat and their relationship to vanilloid receptors in rat dorsal root ganglion neurons

Heat transduction mechanisms in primary nociceptive afferents have been suggested to involve a vanilloid receptor channel with high calcium permeability. To characterize the changes in free cytosolic calcium evoked by noxious heat stimuli (< or =51 degrees C, 10s), we performed microfluorometric measurements in acutely dissociated small dorsal root ganglion neurons (< or =32.5 microm) of adult rats using the dye FURA-2. Only neurons that responded with a reversible increase in intracellular calcium to high potassium were evaluated. Heat-induced calcium transients (exceeding mean + 3S.D. of the temperature dependence of the dye) were found in 66 of 105 neurons. These transients increased non-linearly with temperature. In contrast, heat-insensitive neurons showed a small linear increase of intracellular calcium throughout the range of 12-49 degrees C, similar to cardiac muscle cells. The vanilloid receptor agonist capsaicin induced calcium transients in 72 of 99 neurons. Capsaicin sensitivity and heat sensitivity were significantly associated (P<0.001, chi(2)-test), but 16 of 34 heat-insensitive cells responded to capsaicin and four of 49 heat-sensitive cells were capsaicin insensitive. The competitive vanilloid receptor antagonist capsazepine (10 microM) reversibly reduced the heat-induced calcium transients by 47+/-13%. In contrast, high potassium-induced calcium transients were not affected by pre-incubation with capsazepine. In calcium-free extracellular solution, the heat-induced rise in intracellular calcium was reduced by 76+/-5%. Heat-induced calcium transients were also reversibly reduced by 75+/-6% in sodium-free solution and by 62+/-7% with the L-type calcium channel blocker nifedipine (5 microM). These results indicate that noxious heat rapidly increases intracellular calcium in nociceptive primary sensory neurons. Heat-sensitive vanilloid receptors are involved in the induction of calcium transients, and calcium is also released from intracellular stores, but the main fraction of calcium passes through voltage-operated calcium channels.

l-Menthol-induced [Ca2+]i increase and impulses in cultured sensory neurons

We investigated the effects of l-menthol on cultured dorsal root ganglion (DRG) cells, instead of free nerve endings of sensory fibers. Using Fura-2 microfluorimetry, we identified a few DRG neurons that showed an increase in intracellular free Ca2+ concentration ([Ca2+]i) in response to l-menthol. They made up only 10% of the neurons activated by a high K+ solution. l-Menthol induced the [Ca2+]i increase in a dose-dependent manner, with an EC50 of 37.9 microM and a Hill coefficient of 0.97. A related compound, cyclohexanol, had no effect. When extracellular Ca2+ was removed, l-menthol did not induce the [Ca2+]i increase. Whole-cell current-clamp recordings revealed that l-menthol induced depolarization (13.2 mV, receptor potential) leading to impulses. We conclude that l-menthol induced the impulses through activation of menthol receptors in a small subset of the cultured sensory neurons.

Mechanosensitive whole-cell currents in cultured rat somatosensory neurons

Mechanosensitive currents in cultured rat dorsal root ganglion (DRG) neurons were analyzed by whole-cell patch clamp experiments. A positive pressure applied through a patch electrode induced an inward current in neurons 20 microm or larger in diameter. Ca(2+)- and Na(+)-depletion experiments revealed two kinds of channels involved in the mechanotransduction. One type of cells (type A) displayed blockade of the inward current in the absence of external Ca(2+); namely, the positive pressure of 10 cmH(2)O induced an inward current of 0.45+/-0.14 nA (mean+/-S.D., n=6) in the normal medium, and 0.08+/-0.07 nA (n=6) in the Ca(2+)-free solution. The current was influenced only a little by the depletion of external Na(+) in type A; the positive pressure induced an inward current of 0.48+/-0.04 nA (n=6) in the normal medium, and 0.39+/-0.06 nA (n=6) in the Na(+)-free solution. In the other type of cells (type B), the current persisted in the absence of Ca(2+); 0.52+/-0.09 nA (n=6) in the normal medium, and 0.35+/-0.09 nA (n=6) in the Ca(2+)-free solution. This type displayed a significant decrease in the inward current in the absence of Na(+); 0.42+/-0.09 nA (n=6) in the normal medium, and 0.23+/-0.08 nA (n=6) in the Na(+)-free solution. We concluded that there are two types of mechanosensitive channels in cultured DRG neurons, a Ca(2+)-selective channel and a non-selective cation channel.

Calcium signaling in cold cells studied in cultured dorsal root ganglion neurons

Thermosensitive cold cells were identified in cultured dorsal root ganglion neurons from newborn rats. The neurons were loaded with a calcium indicator, Fura-PE3, and the change in intracellular Ca2+ concentration ([Ca2+]i) of the neurons was measured with microfluorimetry. Thirteen per cent of the cells responded to the cold stimulation. The diameter of the responder cells was 16.3+/-3.2 microm (mean+/-S.D., n = 25). The lowering of the temperature from 35 degrees C to 20 degrees C increased [Ca2+]i from 59.6+/-10.6 nM to 203.4+/-14.8 nM (n = 25). The [Ca2+]i response was dependent on the intensity of the cold stimulation. The depletion of extracellular Ca2+ diminished the Ca2+ elevation. However, a Na(+)-free condition did not influence the response. We concluded that the cold stimulation opens Ca2(+)-permeable channels in putative cold cells from dorsal root ganglion neurons.

Pain

Advances in our understanding of the activation of peripheral damage-sensing neurons (nociceptors) over the past year have been complemented by electrophysiological and imaging studies of central nervous system pain-related centres. The manipulation of gene expression in a reversible and cell type specific way combined with imaging and electrophysiological studies holds promise for helping us to identify the spatial and molecular substrates of pain perception with increasing precision and gives hope for improved analgesic therapies.