Spinal Circuits Transmitting Mechanical Pain and Itch The Harvard community has made this article openly available. Please share how this access benefits you. Your story matters Citation Duan, Bo, Longzhen Cheng, and Qiufu Ma. 2017. “Spinal Circuits Transmitting Mechanical Pain and Itch.” Neuroscience Bulletin 34 (1): 186-193. doi:10.1007/s12264-017-0136-z. http:// dx.doi.org/10.1007/s12264-017-0136-z. Published Version doi:10.1007/s12264-017-0136-z Citable link http://nrs.harvard.edu/urn-3:HUL.InstRepos:35014869 Terms of Use This article was downloaded from Harvard University’s DASH repository, and is made available under the terms and conditions applicable to Other Posted Material, as set forth at http:// nrs.harvard.edu/urn-3:HUL.InstRepos:dash.current.terms-of- use#LAA Neurosci. Bull. February, 2018, 34(1):186–193 www.neurosci.cn https://doi.org/10.1007/s12264-017-0136-z www.springer.com/12264 REVIEW Spinal Circuits Transmitting Mechanical Pain and Itch 1 2 3 Bo Duan • Longzhen Cheng • Qiufu Ma Received: 15 February 2017 / Accepted: 1 April 2017 / Published online: 8 May 2017 Ó The Author(s) 2017. This article is an open access publication Abstract In 1905, Henry Head first suggested that trans- itch evoked by innocuous mechanical stimuli [1–10]. mission of pain-related protopathic information can be Chronic pain can be caused by tissue inflammation negatively modulated by inputs from afferents sensing (inflammatory pain) or by lesions of the nervous system innocuous touch and temperature. In 1965, Melzak and (neuropathic pain). Studies in the past decades have Wall proposed a more concrete gate control theory of pain revealed many mechanisms leading to allodynia. In one that highlights the interaction between unmyelinated C scenario, peripheral sensitization following inflammation fibers and myelinated A fibers in pain transmission. Here allows high-threshold nociceptors to gain the ability to we review the current understanding of the spinal micro- respond to innocuous mechanical stimuli (for details, see circuits transmitting and gating mechanical pain or itch. the recent reviews [11–15]). The other scenario is partly We also discuss how disruption of the gate control could based on the gate control theory first postulated by Ronald cause pain or itch evoked by innocuous mechanical stimuli, Melzak and Patrick Wall in 1965 and then revised in a hallmark symptom for many chronic pain or itch patients. subsequent years [5, 16, 17], allowing low-threshold mechanoreceptors (LTMRs) to activate pain transmission Keywords Pain Á Itch Á Gate control Á Spinal cord neurons under pathological conditions. In this mini-review, we provide an update on the identities of spinal neurons Management of chronic pain and itch remains a major that form the microcircuits underlying the gate control of medical challenge. One common symptom seen in these mechanical pain or itch. patients is the presence of allodynia or alloknesis-pain or Pain Theories and Mapping Dorsal Spinal Circuits & Bo Duan [email protected] The mammalian dorsal spinal cord transmits and processes & Longzhen Cheng information related to a variety of sensory modalities, [email protected] including pain, itch, temperature, and touch [5, 18]. It is & Qiufu Ma organized into distinct laminae [18, 19]. Unmyelinated C [email protected] afferents and thinly-myelinated Ad sensory afferents that 1 Department of Molecular, Cellular, and Developmental transmit pain, itch, and temperature primarily terminate in Biology, University of Michigan, 830 North University Ave, laminae I/II, as well as lamina V and other more ventral Ann Arbor, MI 48109, USA laminae [5, 18]. Various classes of LTMRs, including 2 Institute of Brain Science, the State Key Laboratory of myelinated Ab fibers, as well as Ad and C fibers, terminate Medical Neurobiology and the Collaborative Innovation from the ventral inner layer of lamina II (vIIi) to lamina V Center for Brain Science, Fudan University, Shang- hai 200032, China [20]. The major output neurons include projection neurons located in lamina I and laminae III-VI, which ascend along 3 Dana-Farber Cancer Institute and Department of Neurobiol- ogy, Harvard Medical School, 1 Jimmy Fund Way, Boston, the anterolateral tract or through the dorsal column [18, 21] MA 02115, USA (Fig. 1A). 123 B. Duan et al.: Spinal Circuits Transmitting Mechanical Pain and Itch 187 One key question in the somatosensory field is to inputs from nociceptors, and their activation evokes pain and understand how the dorsal horn transmits distinct sensory other action systems. Second, transmission of nociceptive modalities. Four different theories, including the specificity information to T neurons can be modulated by descending versus gate control theories discussed here, have been inputs from various brain regions. Third, T neurons concur- proposed in past centuries, as recently reviewed by Perl and rently receive excitatory inputs from LTMRs, but these others [22–25]. The specificity hypothesis suggests the inputs are gated via feedforward activation of local existence of specific neural circuits transmitting different inhibitory interneurons (‘‘IN’’), such that innocuous sensory modalities. Regarding pain-related information mechanical stimuli normally suppress acute nociceptive transmission, the specificity hypothesis is supported by the pain. Fourth, strong nociceptive inputs, as well as plasticity discovery of nociceptive-specific (NS) neurons in the late induced by inflammation or nerve injury, somehow attenuate 1960s and early 1970s, based on extracellular recordings the inhibitory inputs from IN neurons and/or sensitize T [26] (but see also below). Primary afferents expressing the neurons, such that normally subthreshold LTMR inputs can G-protein coupled receptor (GPCR) MrgrpA3 and spinal now sufficiently activate T neurons to evoke allodynia neurons expressing the gastrin-releasing peptide receptor (Fig. 1B). (GRPR) are required selectively to transmit chemical itch, Recent years have seen important progress in charac- but not pain, providing further support for the specificity terizing the spinal circuits that transmit mechanical pain or hypothesis [27–30]. The gate control theory discussed in this itch. Together with the Martyn Goulding lab at the Salk review highlights crosstalk among different afferents in Institute, we have been using an intersectional genetic shaping sensory information transmission. Sensory afferent strategy to identify spinal neurons involved in the trans- crosstalk is clearly suggested by the Thermal-Grill illusion mission and gating of distinct modalities [34–36]. This discovered in 1896, showing that cold and warm stimulations intersectional genetic strategy allows us to ablate or silence in alternative skin regions generate paradoxical hot or even specific spinal neurons that are defined by co-expression of burning pain percepts [31, 32]. In 1905, Henry Head the Cre DNA recombinase driven from a specific gene and performed nerve lesion on his own hand, and, based on the the Flpo recombinase driven from the Lbx1 gene whose differential regeneration speeds of different sensory affer- expression is restricted to the dorsal spinal cord and dorsal ents and the progressive change in perception in response to hindbrain [37, 38]. As such, only dorsal spinal/hindbrain various sensory stimuli, he concluded that the crude excitatory or inhibitory neurons that co-express XCre (X protopathic pain perception generated by noxious stimuli indicates a specific gene) and Lbx1Flpo are ablated or can be attenuated by inputs from epicritic afferents that sense silenced, without affecting Cre-expressing neurons in the innocuous touch and temperatures [33], leading to the peripheral nervous system or in the brain [34–36]. Mean- prototype of the gate control theory. In 1965, Melzack and while, several labs combined genetic and viral tools to Wall then proposed a more concrete gate control theory that manipulate specific populations of spinal neurons [39–42]. was built on both clinical observations and electrophysio- Subsequent behavioral and electrophysiological studies logical recordings [16]. Gate control theory has several have now provided considerable insights into the trans- features (Fig. 1B), following incorporation of the discovery mission of mechanical pain and/or itch in the dorsal spinal of the large number of nociceptors by Perl and his colleagues. cord. In this review, we focus on the identities of T neurons First, spinal transmission (‘‘T’’) neurons normally receive for the transmission of mechanical pain, the pathways Fig. 1 Laminar organization of the spinal dorsal horn. A Lami- nar organization of dorsal horn and primary afferent inputs, modified from Craig [19]. B The gate control theory proposed in 1965. T, transmission neurons; IN, inhibitory neurons in the substantia gelatinosa (lamina II) of the dorsal horn. 123 188 Neurosci. Bull. February, 2018, 34(1):186–193 linking LTMRs to T neurons, the characterization of IN neurons for the gate control of mechanical pain or itch, and the identities of relevant LTMRs. Spinal ‘‘T’’ Neurons Transmitting Mechanical Pain Spinal ‘‘T’’ neurons for mechanical pain transmission are defined as excitatory neurons that receive monosynaptic inputs from mechano-sensitive nociceptors. ‘‘T’’ neurons do not necessarily represent ascending projection neurons as suggested by the original gate control diagram [16]. We found that spinal neurons in the somatostatin (SOM) lineage, marked by SOMCre in which the Cre recombinase is driven
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