Many primary sensory neurons are polymodal, responding to multiple stimulus modalities (chemical, thermal, or mechanical), yet each modality is recognized differently. While polymodality implies that stimulus encoding occurs in higher centers such as the spinal cord or brain, recent sensory neuron ablation studies find that behavioral responses to different modalities require distinct subpopulations, suggesting the existence of modality-specific labeled-lines at the level of the sensory afferent. Here we provide evidence that neurons expressing TRPM8, a cold- and menthol-gated channel required for normal cold responses in mammals, represents a labeled-line solely for cold sensation. We examined the behavioral significance of conditionally ablating TRPM8+ neurons in adult mice, finding that, like animals lacking TRPM8 channels (Trpm8−/−), animals depleted of TRPM8 neurons (ablated) are insensitive to cool to painfully cold temperatures. Ablated animals showed little aversion to noxious cold and did not distinguish between cold and a preferred warm temperature, a phenotype more profound than that of Trpm8−/− mice which exhibit only partial cold avoidance and preference behaviors. In addition to acute responses, cold pain associated with inflammation and nerve injury was significantly attenuated in ablated and Trpm8−/− mice. Moreover, cooling-induced analgesia after nerve injury was abolished in both genotypes. Lastly, heat, mechanical, and proprioceptive behaviors were normal in ablated mice, demonstrating that TRPM8 neurons are dispensable for other somatosensory modalities. Together these data show that while some limited cold sensitivity remains in Trpm8−/− mice, TRPM8 neurons are required for the breadth of behavioral responses evoked by cold temperatures.
Chronic pain associated with injury or disease can result from dysfunction of sensory afferents whereby the threshold for activation of pain-sensing neurons (nociceptors) is lowered. Neurotrophic factors control nociceptor development and survival, but also induce sensitization through activation of their cognate receptors, attributable, in part, to the modulation of ion channel function. Thermal pain is mediated by channels of the transient receptor potential (TRP) family, including the cold and menthol receptor TRPM8. Although it has been shown that TRPM8 is involved in cold hypersensitivity, the molecular mechanisms underlying this pain modality are unknown. Using microarray analyses to identify mouse genes enriched in TRPM8 neurons, we found that the glial cell line-derived neurotrophic factor (GDNF) family receptor GFR␣3 is expressed in a subpopulation of TRPM8 sensory neurons that have the neurochemical profile of cold nociceptors. Moreover, we found that artemin, the specific GFR␣3 ligand that evokes heat hyperalgesia, robustly sensitized cold responses in a TRPM8-dependent manner in mice. In contrast, GFR␣1 and GFR␣2 are not coexpressed with TRPM8 and their respective ligands GDNF and neurturin did not induce cold pain, whereas they did evoke heat hyperalgesia. Nerve growth factor induced mild cold sensitization, consistent with TrkA expression in TRPM8 neurons. However, bradykinin failed to alter cold sensitivity even though its receptor expresses in a subset of TRPM8 neurons. These results show for the first time that only select neurotrophic factors induce cold sensitization through TRPM8 in vivo, unlike the broad range of proalgesic agents capable of promoting heat hyperalgesia.
Over a decade and a half of intensive study has shown that the Transient Receptor Potential family ion channels TRPV1 and TRPM8 are the primary sensors of heat and cold temperatures in the peripheral nervous system. TRPV homologues and TRPA1 are also implicated, but recent genetic evidence has diminished their significance in thermosensation and suggests that a number of newly identified thermosensitive channels, including TRPM3, two-pore potassium channels, and the chloride channel Ano1, require further consideration. In addition to novel thermostransducers, recent genetic and pharmacological approaches have begun to elucidate the afferent neurocircuits underlying temperature sensation, continuing the rapid expansion in our understanding of the cellular and molecular basis of thermosensation that began with the discovery of TRPV1 and TRPM8.
Tissue injury prompts the release of a number of proalgesic molecules that induce acute and chronic pain by sensitizing pain-sensing neurons (nociceptors) to heat and mechanical stimuli. In contrast, many proalgesics have no effect on cold sensitivity or can inhibit cold-sensitive neurons and diminish cooling-mediated pain relief (analgesia). Nonetheless, cold pain (allodynia) is prevalent in many inflammatory and neuropathic pain settings, with little known of the mechanisms promoting pain vs. those dampening analgesia. Here, we show that cold allodynia induced by inflammation, nerve injury, and chemotherapeutics is abolished in mice lacking the neurotrophic factor receptor glial cell line-derived neurotrophic factor family of receptors-α3 (GFRα3). Furthermore, established cold allodynia is blocked in animals treated with neutralizing antibodies against the GFRα3 ligand, artemin. In contrast, heat and mechanical pain are unchanged, and results show that, in striking contrast to the redundant mechanisms sensitizing other modalities after an insult, cold allodynia is mediated exclusively by a single molecular pathway, suggesting that artemin-GFRα3 signaling can be targeted to selectively treat cold pain.W hen pain continues past its usefulness as a warning of potential tissue damage, it becomes a debilitating condition for which few viable treatments are currently available. The result can be an exacerbation of pain in response to both innocuous (allodynia) and noxious (hyperalgesia) stimuli (1). For example, pain felt with normally pleasant mild cooling (cold allodynia) occurs in many pathological conditions, such as fibromyalgia, multiple sclerosis, stroke, and chemotherapeutic-induced polyneuropathy, but what underlies this specific form of pain at the cellular or molecular level is largely unknown (2-5). Pain-sensing afferent neurons (nociceptors) are sensitized during injury or disease, in part, by a vast array of proalgesic compounds termed the "inflammatory soup" (e.g., neurotrophic factors, protons, bradykinin, prostaglandins, and ATP) (1). These substances are released locally at the site of injury by infiltrating immune cells, such as macrophages, neutrophils, and T cells, as well as resident cells, including keratinocytes and mast cells (6), and either directly activate sensory receptors or sensitize them to subsequent stimuli (7). Moreover, prolonged inflammation can lead to central sensitization (in the spinal cord and brain) and bring about long-lasting chronic pain that persists after acute inflammation has resolved. Thus, a better understanding of the molecules involved in neuroinflammation may lead to therapeutic options for acute and chronic pain.Of the range of proalgesics known to promote pain, only nerve growth factor (NGF) and the glial cell line-derived neurotrophic factor family ligand (GFL) artemin have been shown to lead to cold hypersensitivity (8-11). Both are major components of the inflammatory soup and produce nociceptor sensitization and pain through their cognate cell surface rece...
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