Calbindin-immunoreactive sensory neurons in dissociated dorsal root ganglion cell cultures of chick embryo: role of culture conditions

Immunoreactivity to calbindin D-28k, a vitamin D-dependent calcium-binding protein, is expressed by neuronal subpopulations of dorsal root ganglia (DRG) in the chick embryo. To determine whether the expression of this phenotypic characteristic is maintained in vitro and controlled by environmental factors, dissociated DRG cell cultures were performed under various conditions. Subpopulations of DRG cells cultured at embryonic day 10 displayed calbindin-immunoreactive cell bodies and neurites in both neuron-enriched or mixed DRG cell cultures. The number of calbindin-immunoreactive ganglion cells increased up to 7-10 days of culture independently of the changes occurring in the whole neuronal population. The presence of non-neuronal cells, which promotes the maturation of the sensory neurons, tended to reduce the percentage of calbindin-immunoreactive cell bodies. Addition of horse serum enhanced both the number of calbindin-positive neurons and the intensity of the immunostaining, but does not prevent the decline of the subpopulation of calbindin-immunoreactive neurons during the second week of culture; on the contrary, the addition of muscular extract to cultures at 10 days maintained the number of calbindin-expressing neurons. While calbindin-immunoreactive cell bodies grown in culture were small- or medium-sized, no correlation was found between cell size and immunostaining density. At the ultrastructural level, the calbindin immunoreaction was distributed throughout the neuroplasm. These results indicate that the expression of calbindin by sensory neurons grown in vitro may be modulated by horse serum-contained factors or interaction with non-neuronal cells. As distinct from horse serum, muscular extract is able to maintain the expression of calbindin by a subpopulation of DRG cells.     

Calbindin-immunoreactive sensory neurons of dorsal root ganglion project to skeletal muscle in the chick

In the chicken dorsal root ganglia, two neuronal subpopulations referred to as A1 and B1 share in common an immunoreactivity to antisera raised to calbindin D-28k but are distinguished by their cytological and ultrastructural characteristics. To determine the peripheral targets innervated by calbindin-immunoreactive neurons in lumbosacral dorsal root ganglia, cryostat sections of various hindlimb tissues were treated with anticalbindin antisera. Calbindin-immunostained axons were clearly detected in skeletal muscle. Large myelinated nerve fibres and afferent axon terminals in neuromuscular spindles were calbindin-immunoreactive; thin unmyelinated nerve fibres were also immunostained in nerve bundles of the perimysium. Since motoneurons and neurons of the autonomic nervous system were devoid of calbindin immunostaining, it was suggested that the immunoreactive axons found in skeletal muscle originate from sensory neurons expressing a calbindin immunoreaction in the dorsal root ganglia. This hypothesis was corroborated after introduction of wheat germ agglutinin coupled with horseradish peroxidase or colloidal gold particles into the sartorius muscle. The retrogradely transported tracer was collected only in ganglion cell bodies which displayed the ultrastructural characteristics of A1 and B1 sensory neurons. On the basis of calbindin immunoreaction and of tracer retrograde transport, it is concluded that ganglion cells of subclasses A1 and B1 contribute to the sensory innervation of skeletal muscle in the chicken.     

Neuronal phenotypes in mouse dorsal root ganglion cell cultures: Enrichment of substance P and calbindin D-28k expressing neurons in a defined medium

The primary sensory neurons in mouse dorsal root ganglia consist of diversified subpopulations which express distinct phenotypic characteristics such as substance P or calbindin D-28k. To determine whether neuronal phenotypes are altered or not in in vitro cultures carried out in a defined synthetic medium, dissociated dorsal root ganglion cells from newborn mice were grown in the alpha-modified minimum essential medium either supplemented with 10% fetal calf serum or serum-free. About 80% of the neurons survived after 5 days of culture in both media, but only 35% or 65% were rescued after 12 days in serum-free or fetal calf serum supplemented medium, respectively. The neuronal subpopulations expressing substance P or calbindin D-28k displayed similar morphological properties in both media and a higher resistance to culture conditions than the whole neuronal cell population, especially in serum-free medium. It is therefore concluded that a defined synthetic medium offers reproducible conditions to culture dorsal root ganglion cells for at least 5 days, stimulates the expression of substance P and enriches preferentially neuronal phenotypes expressing substance P or calbindin D-28k, for a longer period of culture.     

Parvalbumin and calbindin D-28 k immunoreactivity in dorsal root ganglia in acquired immunodeficiency syndrome

Various degrees of neuronal degeneration have been found in lumbosacral dorsal root ganglia of patients with acquired immunodeficiency syndrome (AIDS). To characterize the subpopulations of primary sensory neurons affected in AIDS. we immunostained dorsal root ganglion tissues from 11 AIDS patients and six controls using antibodies to the calcium binding proteins, parvalbumin and calbindin D-28 k. In controls, the proportion of neurons containing parvalbumin and calbindin was 18.0% and 22.4%, respectively. The majority of parvalbumin-positive neurons, which are thought to be proprioceptive neurons, were of medium to large size, while calbindin was found in both large- and small-sized neurons. The density of parvalbumin-immunoreactive neurons was reduced by 7.3% in AIDS patients, but the density of calbindin-immunoreactive neurons was preserved. Furthermore, in AIDS cases, the number of parvalbumin-positive neurons was reduced more in dorsal root ganglia in which human immunodeficiency virus (HIV) antigen was detected than in HIV-negative ganglia. These results suggest that specific subpopulations of sensory neurons positive for parvalbumin may be differentially affected over the course of AIDS, and that this could be related to peripheral neuropathy which frequently occurs in the late stages of AIDS.     

The influence of skeletal muscle on the electrical excitability of dorsal root ganglion neurons in culture

Dorsal root ganglion (DRG) neurons from embryonic mice grown in coculture with dissociated skeletal muscle or in skeletal muscle conditioned medium (CM) showed an increased incidence of repetitive firing of action potentials when injected with sustained (60-100 msec) depolarizing current. This is in contrast to DRG neurons grown in monoculture and normal medium, which exhibit such behavior far less frequently. The first action potential showed less sensitivity to block with TTX and more sensitivity to Ca2+ channel blockers than the subsequent action potentials. The increased incidence of repetitive firing occurred when CM was added after as few as 2 or as many as 22 d in culture and with as little as 1-7 hr exposure to CM. This effect of CM cannot be mimicked by NGF or by coculture with cells from embryonic spinal cord (Peacock et al., 1973), can be eliminated by heating the CM at 56 degrees C for 30 min, and partially reversed following short exposure to CM. These results indicate that skeletal muscle releases some heat-labile factor(s) that can cause repetitive firing and, in addition, significant decrease in input resistance in the CM-treated neurons and a depression of the anomalous rectification, neither of which could account for the increase in repetitive firing.     

NF-L and peripherin immunoreactivities define distinct classes of rat sensory ganglion cells.

Double immunofluorescence studies using antibodies against NF-L and peripherin revealed three distinct subpopulations of neurons in rat dorsal root ganglia (DRG). In the adult rat, 46% of the DRG neurons were small and peripherin-positive (NF-L-negative), and 48% were large and NF-L-positive (peripherin-negative). About 6% were both peripherin- and NF-L-positive. All of the DRG neurons reacted with antibodies to NF-M and nonphosphorylation-dependent or phosphorylation-independent antibodies to NF-H. The neuropeptides were predominantly found in the peripherin-positive small cell population. Eighty-seven percent of the peripherin-positive small cell population contained substance P immunoreactivity, while 43% of this cell population contained CGRP. In contrast, only 18-24% of the NF-L-positive large-cell population contained neuropeptides, and these were primarily in a smaller sized subpopulation. Similar patterns of antigen representation were observed in neonatal (PN2) DRG cell populations. Tissue cultures of sensory ganglion cells from PN2 DRG, in serum-free medium, stably maintained exclusively peripherin-positive neurons, with about 5% of these containing coexistent NF-L immunoreactivity. Very high levels of neuropeptide gene expression were exhibited by these postnatal neurons in culture.     

A procedure for selecting and culturing subpopulations of neurons from rat dorsal root ganglia using magnetic beads

Current protocols for preparing primary sensory neuron cultures are inadequate when studying individual subpopulations of dorsal root ganglion (DRG) neurons. The DRG is made up of a heterogeneous population of cells, making it difficult to study treatment effects on any given population in mass cultures. Thus, we describe a procedure using magnetic beads from Dynal to select and plate viable populations of neurons based on expression of specific cell surface markers. We show that, by the use of the lectin IB4, we can select a highly enriched viable subpopulation of GDNF-responsive DRG neurons, leaving a viable population of non-selected IB4-ve, Trk+ve neurons. Key factors for successful cultures are (i) quick and careful dissection of DRGs from 4- to 5-week-old Sprague-Dawley rats, (ii) adequate removal of debris and non-neuronal contamination and (iii) gentle handling of bead-bound cells during selection.     

Glutamine Synthetase is Expressed by Primary Sensory Neurons from Chick Embryos In Vitro but not In Vivo: Influence of Skeletal Muscle Extract

Glutamine synthetase (GS) catalyses the ATP-dependent formation of glutamine from glutamate and ammonia. To determine whether dorsal root ganglion (DRG) cells from chick embryos express the enzyme in vivo or in vitro, GS was detected by immunocytochemical reaction either in vibratome sections of DRG or in dissociated DRG cell cultures. The immunocytochemical detection of GS showed that in vivo the DRG taken from chick embryos at day 10 (E10), E14, E18 or from chickens after hatching were free of any GS-positive ganglion cells; in contrast, in neuron-enriched cultures of DRG cells grown in vitro at E10, virtually all the neuronal cells (98.6 +/- 1.0%) express GS at 3, 5 or 7 days of culture. In mixed DRG cell cultures, only 83.6+/-4.6% of the neurons displayed a GS-immunoreactivity. In both culture conditions, neither the presence of horse serum nor the age of the culture appeared to affect the percentage of neurons which displayed a GS-immunoreactivity. After [3H]glutamine uptake, radioautographs revealed that only 80% of the neurons were labelled in neuron-enriched DRG cell cultures while 96% of the neurons were radioactive in mixed DRG cell cultures. Furthermore the most heavily [3H]glutamine-labelled neurons were exclusively found in mixed DRG cell cultures. Combination of both immunocytochemical detection of GS and radioautography after [3H]glutamine uptake showed that strongly GS-immunostained neurons corresponded to poorly radioactive ones and vice versa. When skeletal muscle extract (ME) was added to DRG cell cultures, the number of GS-positive neurons was reduced to 77.5 +/- 2.5% in neuron-enriched cultures or to 43.6 +/- 3.8% in mixed DRG cell cultures; in both types of culture, the intensity of the neuronal immunostaining was depressed. Furthermore, combined action of ME and non-neuronal cells potentiates the enzyme repression exerted separately by ME or non-neuronal cells. Since GS-immunoreactivity is expressed in DRG cells grown in vitro, but not in vivo, it is suggested that microenvironmental factors influence the expression of GS. More specifically, the repression of GS by primary sensory neurons grown in vitro may be strongly induced by soluble factors present in skeletal muscle, and to a lesser extent in brain, and potentiated by non-neuronal cells.     

Coexistence of calbindin D-28k and NADPH-diaphorase in vagal and glossopharyngeal sensory neurons of the rat

The presence and coexistence of calbindin D-28k-immunoreactivity (ir) and nicotinamide adenosine dinucleotide phosphate (NADPH)-diaphorase activity (a marker of neurons that are presumed to convert L-arginine to L-citrulline and nitric oxide) were examined in the glossopharyngeal and vagal sensory ganglia (jugular, petrosal and nodose ganglia) of the rat. Calbindin D-28k-ir nerve cells were found in moderate and large numbers in the petrosal and nodose ganglia, respectively. Some calbindin D-28k-ir nerve cells were also observed in the jugular ganglion. NADPH-diaphorase positive nerve cells were localized to the jugular and nodose ganglia and were rare in the petrosal ganglion. A considerable portion (33–51%) of the NADPH-diaphorase positive neurons in these ganglia colocalized calbindin D-28k-ir. The presence and colocalization of calbindin D-28k-ir and NADPH-diaphorase activity in neurotransmitter-identified subpopulations of visceral sensory neurons were also studied. In all three ganglia, calcitonin gene-related peptide (CGRP)-ir was present in many NADPH-diaphorase positive neurons, a subset of which also contained calbindin D-28k-ir. In the nodose ganglion, many (42%) of tyrosine hydroxylase (TH)-ir neurons also contained NADPH diaphorase activity but did not contain calbindin D-28k-ir. These data are consistent with a potential co-operative role for calbindin D-28k and NADPH-diaphorase in the functions of a subpopulation of vagal and glossopharyngeal sensory neurons.     

Expression of sensory neuron antigens by a dorsal root ganglion cell line, F-11

The F-11 cell line is a fusion product of embryonic rat dorsal root ganglion (DRG) cells with mouse neuroblastoma cell line N18TG-2 (Platika, D., Boulos, M.H., Baizer, L. and Fishman, M.C., Proc. Natl. Acad. Sci. U.S.A., 82 (1985) 3499-3503). F-11 cells were uniformly labelled using a monoclonal antibody (RT-97) to the 200 kDa subunit of neurofilament protein, which labels a subpopulation of adult rat DRG neurons. F-11 cells did not stain for antigenic markers of fibroblasts or Schwann/satellite cells which are also present in DRG. Monoclonal antibodies that recognize cell surface carbohydrates have been shown to label subpopulations of DRG neurons. The stage-specific embryonic antigens SSEA-3 and SSEA-4, and the antigen recognized by B23D8, were expressed by some F-11 cells but not by the neuroblastoma parent of the hybrid cells. SSEA-3 was expressed by about 20% of the F-11 cells, whereas 40-60% expressed SSEA-4 or the antigen recognized by B23D8. The stability of F-11 cell subpopulations for sensory antigen expression was demonstrated by isolating single cells and growing the progeny as clonal lines. In some subclones, nearly 100% of the cells stably expressed SSEA-4 and/or B23D8, or failed to stain with anti-SSEA-4, anti-SSEA-3, or B23D8 over 12 passages. Other subclones were unstable for the expression of these antigens. This study demonstrates the derivation of the F-11 cell line from sensory neurons but also indicates that multiple phenotypes of varying stability are present in this line. This information is important for the use of this line as a model for DRG neurons.     

Expression of interleukin-1 beta in rat dorsal root ganglia

The expression of interleukin-1beta was examined in dorsal root ganglion (DRG) neurons from adult rats using non-radioactive in situ hybridization and immunocytochemistry. At all spinal levels, approximately 70% of the DRG neurons appeared to express IL-1beta mRNA; about 80% of these DRG neurons actually appeared to produce the IL-1beta protein at markedly varying levels. The expression of IL-1beta was found in large as well as in intermediate diameter sensory neurons but only sporadically in the population of small sensory neurons. The population of IL-1beta immunopositive sensory neurons included most of the large calretinin-positive Ia afferents, but only a few of the small substance P/CGRP positive sensory neurons. In situ hybridization staining for the detection of type 1 IL-1 receptor showed expression of this receptor by most of the sensory neurons as well as by supportive glial-like cells, presumably satellite cells. The functional significance of IL-1beta in the DRG neurons needs to be elucidated, but we speculate that IL-1beta produced by DRG neurons may be an auto/paracrine signalling molecule in sensory transmission.     

Leukaemia Inhibitory Factor Induced in the Sciatic Nerve after Axotomy is Involved in the Induction of Galanin in Sensory Neurons

Dramatic changes occur in neuropeptide expression in sensory and sympathetic neurons following axonal injury. Based on the finding that the cytokine leukemia inhibitory factor (LIF) plays an important role in mediating these changes in sympathetic neurons, its participation in triggering changes in sensory neurons was examined. By the use of transgenic mice in which the LIF gene had been knocked out, LIF was found to contribute to the induction of galanin expression in dorsal root ganglia (DRG) after sciatic nerve lesion. On the other hand, two other neuropeptide changes that occur in DRG under these conditions, the reduction of substance P and induction of neuropeptide Y, were independent of LIF expression. In the sympathetic superior cervical ganglion, transection of the postganglionic nerves close to the ganglion resulted in a rapid induction of LIF mRNA in the ganglion and in the lesioned nerve trunk. In contrast, transection of the sciatic nerve close to or distant from the DRG caused a rapid induction of LIF mRNA in the lesioned nerve, but not in the DRG. DRG were capable of making substantial amounts of LIF mRNA when placed in explant cultures, but, in vivo , only a slight induction was found even when both central and peripheral nerve processes of these sensory neurons were transected. These latter observations suggest that, in contrast to the superior cervical ganglia, the DRG environment inhibits the lesion-induced expression of LIF in vivo , and/or explanted DRG produce stimulatory signals not found in vivo. , Together with the data on the induction of galanin, these observations provide evidence that LIF, generated at a site at some distance from the ganglion, is involved in triggering part of the cell body reaction in sensory neurons.     

Appearance and distribution of neuron-specific enolase and calbindin (CaBP 28 kDa) in the developing human inner ear

The onset and development of neuron-specific enolase (NSE) and calbindin immunoreactivities were studied in the inner ear of human fetuses aged from 6-7 to 14 weeks of gestation. NSE occurred very early in ganglion neurons. Its appearance in vestibular sensory cells at 8 weeks coincided with the formation of the first afferent synapses, and showed an apex/base gradient in the cristae. Calbindin was found in vestibular ganglion neurons at 6-7 weeks and in the cochlear ganglion neurons at 8-9 weeks. Vestibular sensory cells and the whole ventral wall of the cochlear duct were stained from 8-9 weeks. At 14 weeks, calbindin staining occurred only in the sensory cells of the cochlear neuroepithelium. Non-neuronal secretory structures, i.e. K?lliker's organ and some cells of the transitional zone of the utricle, were also reactive. Staining appeared in K?lliker's organ with a base to apex gradient and disappeared from it with an internal to external gradient. Calbindin appeared in vestibular sensory cells later than NSE staining, synapse formation and sensory hair bundle differentiation. By contrast in the cochlea, calbindin staining appeared in the neuroepithelium before sensory cell differentiation, but remained only in the hair cells after they had differentiated and been contacted by the afferent fibers.     

Involvement of IGF-1 and IGFBP-1 and -3 in Axon-Schwann Cell Interactions

Insulin-like growth factor-I (IGF-I) promotes proliferation, differentiation and survival of Schwann cells (SC). Moreover, an effect of IGF-I on axon regeneration has been proposed. However, although IGF-I expression has been shown in postnatal SC and in SC precursors thus suggesting an autocrine regulation of SC survival, release of the trophic factor by SC has not been clearly demonstrated. To investigate the role of the IGF system, we studied the supernatant of primary SC cultures, purified sensory neuron cultures, and co-cultures of SC and sensory neurons. Moreover, since in its free form IGF-I interacts with specific binding proteins (IGFBPs) whose active role in modulating the effects of IGF-I is increasingly recognized, in the same culture systems we also evaluated levels of IGFBP-1 and -3. We established SC, sensory neuron and SC/sensory neuron cultures according to classical procedures. Purified SC (87,500 cells/dish) were grown in presence of serum, forskolin, cholera toxin and bovine pituitary extract. Purified sensory neurons were grown in the presence of serum and NGF; part of it was maintained alone and the rest was added with SC (87,500 cells/dish) and grown in a co-culture system. After 1 month all cultures were washed with PBS and grown for at least 4 days in a serum-free medium before collecting their conditioned media (CM) for chromatography assays. Similar IGF-I levels were found into the CM of SC and of sensory neurons when grown as purified cultures (94.40 vs 73.80 ng/5×10⁶ cell). Instead, higher amounts of IGF-I were detected into the medium of SC/sensory neurons co-cultures (277.70 ng/5×10⁶ cell). IGFBP-1 and -3 production was also found in both SC and sensory neuron purified cultures, but their expression was clearly higher in neurons compared to SC (0.74 vs 0.28 ng/5×10⁶ cell for IGFBP-1 and 4.48 vs 1.77 ng/5×10⁶ cell for IGFBP-3). Furthermore, SC/sensory neuron co-cultures maintained high levels of IGFBP-3 (3.93 ng/5×10⁶) but not of IGFBP-1 (0.28 ng/5×10⁶). In conclusion, IGF-1 is produced by both SC and pure sensory neurons, but co-culturing the two cell populations results in a possible reciprocal stimulation to synthesize this growth factor. Moreover, the decrease of IGFBP-1 in the medium of co-cultures could be due to the production of IGFBP proteases by SC. This action could be a mechanism to increase IGF-1 availability to the specific receptor.     

Substance P-like-immunoreactive sensory neurons in dorsal root ganglia of the chick embryo: ontogenesis and influence of peripheral targets.

The expression of substance P (SP) was studied in sensory neurons of developing chick lumbosacral dorsal root ganglia (DRG) by using a mixture of periodic acid, lysine and paraformaldehyde as fixative and a monoclonal antibody for SP-like immunostaining. The first SP-like-immunoreactive DRG cells appeared first at E5, then rapidly increased in number to reach a peak (88% of ganglion cells) at E8, and finally declined (59% at E12, 51% after hatching). The fall of the SP-like-positive DRG cells resulted from two concomitant events affecting a subset of small B-neurons: a loss of neuronal SP-like immunoreactivity and cell death. After one hindlimb resection at an early (E6) or late (E12) stage of development (that is before or after establishment of peripheral connections), the DRG were examined 6 days later. In both cases, a drastic neuronal death occurred in the ispilateral DRG. However, the resection at E6 did not change the percentage of SP-like-positive neurons, while the resection at E12 severely reduced the proportion of SP-like-immunoreactive DRG cells (25%). In conclusion, connections established between DRG and peripheral target tissues not only promote the survival of sensory neurons, but also control the maintenance of SP-like-expression. Factors issued from innervated targets such as NGF would support the survival of SP-expressing DRG cells and enhance their SP content while other factors present in skeletal muscle or skin would hinder SP expression and therefore lower SP levels in a subset of primary sensory neurons.     

Sensory neurons regulate immunoglobulin secretion of spleen cells: cellular analysis of bidirectional communications between neurons and immune cells

The effects of primary sensory neurons in the dorsal root ganglia (DRG) on immunoglobulin (Ig)-secreting activity of spleen cells were investigated in culture. The conditioned medium (CM) of normal spleen cells stimulated DRG neurons to release neurokinin A which increased the number of Ig-secreting spleen cells. In contrast, the CM of concanavalin A-induced suppressor spleen cells induced the release of vasoactive intestinal peptide, an inhibitor of Ig secretion of spleen, from DRG neurons. These findings indicate that sensory neurons can help and suppress Ig secretion, and these bidirectional activities are controlled by the factors released from immune cells.     

Co-localized but target-unrelated expression of vasoactive intestinal polypeptide and galanin in rat dorsal root ganglion neurons after peripheral nerve crush injury

Expression of vasoactive intestinal polypeptide (VIP) and galanin in dorsal root ganglion (DRG) neurons is known to be induced by peripheral nerve injury. We investigated (1) whether VIP and galanin were co-expressed by DRG neurons and (2) whether such neurons innervated specified peripheral targets (visceral, cutaneous or muscular). An antibody to the 200 kDa neurofilament subunit (NF200) was used as a marker for large type-A cells in the DRG. VIP and galanin were respectively observed in 22% and 67% of DRG neurons at the L5 spinal level after crushing of the sciatic nerve. Most VIP-containing neurons were small type-B cells (about 90%) and approximately 95% of VIP-containing neurons also showed galanin-like immunoreactivity. Galanin was expressed by both large type-A and small type-B cells. Immunocytochemistry combined with a retrograde tracer revealed that about 70-80% of the small type-B cells in each sensory division displayed VIP-like immunoreactivity, and that most of the tracer-labeled neurons also expressed galanin. These findings suggest that the expression VIP and/or galanin in response to peripheral nerve crush injury is a property common to visceral, cutaneous and muscular sensory neurons.     

Cellular subtype distribution and developmental regulation of TRPC channel members in the mouse dorsal root ganglion

Transient receptor potential (TRP) channels play essential roles in sensory physiology and their expression in different classes of sensory neurons reflect distinct receptive properties of these neurons. While expression of the TRPV, TRPA, and to a certain degree TRPM classes of channels has been studied in sensory neurons, little is known about the expression and regulation of TRPC channels. In this study we examined the regulation of all TRPC members (TRPC1-C7) throughout embryonic and postnatal development of the dorsal root ganglion (DRG) and nodose ganglion (NG). In adult mice, mRNAs for all channels were present in the DRG, with TRPC1, 3, and 6 being the most abundant, TRPC2, C4, and C5 at lower levels, and TRPC7 at very low levels. While TRPC2 mRNAs were downregulated from high levels at embryonic (E) day 12 and E14 until adult, TRPC4, C5, and C7 expressions increased from E12 to peak levels at E18. TRPC1, C3, and C6, the most abundant TRPC channel mRNAs, increased progressively from E12 to adult. Expression and regulation of TRPC channels mRNAs in the NG were unexpectedly similar to the DRG. TRPC1 and C2 was expressed in the neurofilament-200 (NF-200)-positive large size subclass of neurons, while TRPC3 mRNAs expression, which stained up to 35% of DRG neurons, was almost exclusively present in nonpeptidergic isolectin B4 (IB4)-positive small size neurons that were largely TRPV1-negative. Our results suggest important roles of the TRPC family of channels in sensory physiology of both nociceptive as well as nonnociceptive classes of neurons.