Visualizing Cold Spots: TRPM8-Expressing Sensory Neurons and Their Projections

Dhaka, Ajay; Earley, Taryn J.; Watson, James P.; Patapoutian, Ardem

doi:10.1523/jneurosci.3976-07.2008

Cited by 299 publications

(340 citation statements)

References 45 publications

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“…Whether TRPM8-mediated analgesia is dependent on peripheral and/or central sites of action is unknown but may be addressed now that TRPM8-expressing neurons and their peripheral and central fibers can be visualized by GFP expression driven by the TRPM8 promoter (76,77). Importantly, studies in humans and mice reveal species differences in pathways sensing innocuous cold: A-fiber block completely suppresses the cold response in humans (78), yet the majority of TRPM8-expressing fibers responsible for innocuous cold transduction in mice have small diameters (76,77) Noxious cold stimuli activate NSC currents and calcium influx (10,79) and decrease K + channel activity (80) and Na + /K + -ATPase function (65) ( Table 3). The temporal dissociation of the qualities of pain/ache vs. prickle/heat to noxious cold (3°C) suggest underlying differences in transduction mechanisms or information processing (66).…”

Section: Transduction Of Noxious Coldmentioning

confidence: 99%

Nociceptors: the sensors of the pain pathway

Dubin

Patapoutian²

2010

J. Clin. Invest.

1,070

856

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Specialized peripheral sensory neurons known as nociceptors alert us to potentially damaging stimuli at the skin by detecting extremes in temperature and pressure and injury-related chemicals, and transducing these stimuli into long-ranging electrical signals that are relayed to higher brain centers. The activation of functionally distinct cutaneous nociceptor populations and the processing of information they convey provide a rich diversity of pain qualities. Current work in this field is providing researchers with a more thorough understanding of nociceptor cell biology at molecular and systems levels and insight that will allow the targeted design of novel pain therapeutics.

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Section: Transduction Of Noxious Coldmentioning

confidence: 99%

Nociceptors: the sensors of the pain pathway

Dubin

Patapoutian²

2010

J. Clin. Invest.

1,070

856

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“…Using mammalian (i.e. mouse) (3,85,183,213) and non-mammalian (i.e. drosophila) (114,298) animal models, these investigations have significantly contributed to our understanding of how temperature is gated at a molecular level.…”

Section: Neurophysiology Of Temperature Sensationmentioning

confidence: 99%

“…Despite in the past 13 years consistent evidence has been provided for the importance of TRPM8 as molecular mediator of cold sensations in a number of mammalian (209,210) and nonmammalian (114) animal models, it is not until recently that the expression of this channel on those specific first order thermo-sensory afferents, which have been repeatedly shown to respond to skin cooling and to convey temperature-dependent sensory inputs within the spino-thalamocortical tract in mammals, has been thoroughly characterized (85). Dhaka et al (85) have shown that in mice, TRPM8 appears to be expressed on a specific population of first order neurons, whose body are located in the dorsal root ganglion, and whose projections terminate in the skin at the level of the stratum spinosum and granulosum (i.e.…”

Section: Non-noxious Cold Transductionmentioning

confidence: 99%

Neurophysiology of Skin Thermal Sensations

Filingeri

2016

Comprehensive Physiology

111

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Undoubtedly, adjusting our thermoregulatory behavior represents the most effective mechanism to maintain thermal homeostasis and ensure survival in the diverse thermal environments that we face on this planet. Remarkably, our thermal behavior is entirely dependent on the ability to detect variations in our internal (i.e. body) and external environment, via sensing changes in skin temperature and wetness. In the past 30 years, we have seen a significant expansion of our understanding of the molecular, neuroanatomical and neurophysiological mechanisms that allow humans to sense temperature and humidity. The discovery of temperature-activated ion channels which gate the generation of action potentials in thermosensitive neurons, along with the characterization of the spino-thalamo-cortical thermosensory pathway, and the development of neural models for the perception of skin wetness, are only some of the recent advances which have provided incredible insights on how biophysical changes in skin temperature and wetness are transduced into those neural signals which constitute the physiological substrate of skin thermal and wetness sensations. Understanding how afferent thermal inputs are integrated and how these contribute to behavioral and autonomic thermoregulatory responses under normal brain function is critical to determine how these mechanisms are disrupted in those neurological conditions which see the concurrent presence of afferent thermosensory abnormalities and efferent thermoregulatory dysfunctions. Furthermore, advancing the knowledge on skin thermal and wetness sensations is crucial to support the development of neuro-prosthetics. In light of the above, this review will focus on the peripheral and central neurophysiological mechanisms underpinning skin thermal and wetness sensations in humans.

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“…TRPV1 expressed in C-fibers is activated by heat (Ͼ43°C) (Caterina et al, 1997), and TRPV1-null mice are defective in sensing noxious heat (Caterina et al, 2000). TRPM8, which senses cold temperatures (Ͻ27°C) (McKemy et al, 2002;Peier et al, 2002), is expressed in nociceptive and nonnociceptive neurons and its loss causes deficiencies in cold sensation (Bautista et al, 2007;Colburn et al, 2007;Dhaka et al, 2007Dhaka et al, , 2008Takashima et al, 2007). TRPA1 is expressed in C-fibers, mostly accompanying TRPV1 , and acts as a sensor for harmful stimuli, although its responsiveness to noxious cold is controversial (Jordt et al, 2004;Bautista et al, 2006;Kwan et al, 2006;Sawada et al, 2007).…”

Section: Introductionmentioning

confidence: 99%