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Education  |   August 2014
Noncoding RNAs: New Players in Chronic Pain
Author Affiliations & Notes
  • Brianna Marie Lutz, B.S.
    From the Department of Anesthesiology, Rutgers Graduate School of Biomedical Sciences (B.M.L.), Department of Anesthesiology (A.B.), and Departments of Anesthesiology, Cell Biology and Molecular Medicine, Pharmacology and Physiology, and Neurology and Neuroscience (Y.-X.T.), New Jersey Medical School, Rutgers, The State University of New Jersey, Newark, New Jersey.
  • Alex Bekker, M.D., Ph.D.
    From the Department of Anesthesiology, Rutgers Graduate School of Biomedical Sciences (B.M.L.), Department of Anesthesiology (A.B.), and Departments of Anesthesiology, Cell Biology and Molecular Medicine, Pharmacology and Physiology, and Neurology and Neuroscience (Y.-X.T.), New Jersey Medical School, Rutgers, The State University of New Jersey, Newark, New Jersey.
  • Yuan-Xiang Tao, M.D., Ph.D.
    From the Department of Anesthesiology, Rutgers Graduate School of Biomedical Sciences (B.M.L.), Department of Anesthesiology (A.B.), and Departments of Anesthesiology, Cell Biology and Molecular Medicine, Pharmacology and Physiology, and Neurology and Neuroscience (Y.-X.T.), New Jersey Medical School, Rutgers, The State University of New Jersey, Newark, New Jersey.
  • Submitted for publication December 19, 2013. Accepted for publication March 12, 2014.
    Submitted for publication December 19, 2013. Accepted for publication March 12, 2014.×
  • Address correspondence to Dr. Tao: Department of Anesthesiology, New Jersey Medical School, Rutgers, The State University of New Jersey, 185 South Orange Avenue, MSB, F-548, Newark, New Jersey 07103. yuanxiang.tao@njms.rutgers.edu. Information on purchasing reprints may be found at www.anesthesiology.org or on the masthead page at the beginning of this issue. Anesthesiology’s articles are made freely accessible to all readers, for personal use only, 6 months from the cover date of the issue.
Article Information
Education / Review Article / Central and Peripheral Nervous Systems / Pain Medicine / Practice Management
Education   |   August 2014
Noncoding RNAs: New Players in Chronic Pain
Anesthesiology 08 2014, Vol.121, 409-417. doi:10.1097/ALN.0000000000000265
Anesthesiology 08 2014, Vol.121, 409-417. doi:10.1097/ALN.0000000000000265
Abstract

Chronic pain, a common clinical symptom, is often treated inadequately or ineffectively in part due to the incomplete understanding of molecular mechanisms that initiate and maintain this disorder. Newly identified noncoding RNAs govern gene expression. Recent studies have shown that peripheral noxious stimuli drive expressional changes in noncoding RNAs and that these changes are associated with pain hypersensitivity under chronic pain conditions. This review first presents current evidence for the peripheral inflammation/nerve injury–induced change in the expression of two types of noncoding RNAs, microRNAs, and Kcna2 antisense RNA, in pain-related regions, particularly in the dorsal root ganglion. The authors then discuss how peripheral noxious stimuli induce such changes. The authors finally explore potential mechanisms of how expressional changes in dorsal root ganglion microRNAs and Kcna2 antisense RNA contribute to the development and maintenance of chronic pain. An understanding of these mechanisms may propose novel therapeutic strategies for preventing and/or treating chronic pain.

This review highlights recent findings regarding the changes in noncoding RNAs in pain-related regions after persistent inflammation and nerve injury, and discusses how noncoding RNAs participate in the development and maintenance of chronic pain.

CHRONIC pain usually caused by inflammation and tissue or nerve injury is a major public health problem worldwide. It is characterized by ongoing or intermittent burning pain, an enhanced response to noxious stimuli (hyperalgesia), and pain in response to normally innocuous stimuli (allodynia). Current treatment for this disorder has had restricted success due to our inadequate understanding of the mechanisms that lead to the initiation and maintenance of chronic pain. It is known that inflammation and nerve injury produce changes in the expression of receptors, enzymes, ion channels, neurotransmitters, neuromodulators, and structural proteins in primary sensory neurons of the dorsal root ganglion (DRG) at both transcriptional and translational levels.1–3  Such changes are considered to contribute to chronic pain development and maintenance.1–3  However, it is unclear how peripheral inflammation or nerve injury alters the expression of these genes and/or proteins in DRG. Understanding this mechanism may enable the development of new strategies to prevent and/or treat chronic pain.
Recent studies suggest that the mechanism for gene regulation involves widespread noncoding (nc) RNAs.4–6  RNA had long been thought to be a simple and intermediary component of gene expression, as it is transcribed from DNA and then translated into proteins in cells. However, it has become increasingly clear that mammalian genomes encode not only protein-coding RNAs but also a vast number of ncRNA transcripts.7  Because the function of each newly identified ncRNA has not been fully elucidated, the common practice is to group ncRNA transcripts based on transcript size: small/short ncRNAs (e.g., microRNAs [miRNAs]; 18 to 200 nucleotides) and long ncRNAs (e.g., native Kcna2 antisense [AS] RNA; >200 nucleotides).7–9  ncRNAs have been systematically identified in the mammalian nervous system, including in pain-related regions.10  They can be regulated and may govern the expression of both protein-coding and noncoding genes. An intriguing association between aberrant expression of ncRNAs and the development of diseases has been demonstrated recently.11,12  Previous studies have shown that peripheral inflammation and nerve injury drive changes in the expression of some miRNAs and Kcna2 AS RNA in DRG.13–16  These changes might be responsible for inflammation/nerve injury–induced alterations of some pain-associated genes, an increase in DRG neuronal excitability, and behavioral pain hypersensitivity.14,16  The evidence indicates that ncRNAs might be new key players in the mechanisms that underlie the development and maintenance of chronic pain.
In this article, we first review current evidence for the changes of two types of ncRNAs, miRNAs and Kcna2 AS RNA, in pain-related regions, particularly in DRG, after peripheral inflammation and nerve injury. We then discuss how peripheral noxious stimuli induce such changes. We finally explore potential mechanisms of how expressional changes in DRG miRNAs and Kcna2 AS RNA contribute to the development and maintenance of chronic pain. This review provides more up-to-date knowledge regarding the role of ncRNAs in the mechanisms of chronic pain.17,18 
miRNAs in Chronic Pain
Formation of miRNAs
Since the discovery of the first miRNA, lin-4 in Caenorhabditis elegans, hundreds of miRNAs have been identified in the nervous system.19–21  These miRNAs are coded by specific genes. Generally, a miRNA molecule is synthesized from a long RNA primary transcript known as a pri-miRNA (fig. 1). In the cellular nucleus, pri-miRNA is cleaved by Drosha, an RNAIII endonuclease, to produce a characteristic stem-loop structure of approximately 60 to 70 nucleotides in length, known as pre-miRNA (fig. 1). After pre-miRNA is exported from the nucleus into the cytoplasm, it is cleaved by Dicer, another RNAIII endonuclease, to produce double-stranded mature miRNA (fig. 1). The latter is either unwound via an unknown helicase or cleaved by the enzyme Ago2 to lead to a single-stranded miRNA (fig. 1).22  The single strands completely or incompletely bind to specific messenger RNA (mRNA) sequences, resulting in degradation or translational repression of target mRNAs.23  A recent link between miRNA-mediated poly(A)-tail length shortening and mRNA destabilization has been reported, suggesting another potential mechanism of ncRNA-mediated gene regulation.24 
Fig. 1.
Formation of mature microRNA (miRNA). miRNA is transcribed from the genome (DNA) via RNA polymerase II (Pol II). The resulting pri-miRNA transcript is then cleaved via the endonuclease Drosha to create a 60–70 nucleotide long pre-miRNA. This transcript is then removed from the nucleus via exportin-5 to the cytoplasm where it is cleaved by Dicer, another endonuclease. The resulting double-stranded mature miRNA is unwound by a helicase or cleaved by Ago2. The single-stranded mature miRNA then acts as the core of RNA-induced silencing complex. This complex guides the miRNA to its target sequence located within the 3’-untranslated region (3’-UTR) of the target messenger RNA (mRNA). Incomplete or complete base-pairing results in degradation of the mRNA or inhibition of translation.
Formation of mature microRNA (miRNA). miRNA is transcribed from the genome (DNA) via RNA polymerase II (Pol II). The resulting pri-miRNA transcript is then cleaved via the endonuclease Drosha to create a 60–70 nucleotide long pre-miRNA. This transcript is then removed from the nucleus via exportin-5 to the cytoplasm where it is cleaved by Dicer, another endonuclease. The resulting double-stranded mature miRNA is unwound by a helicase or cleaved by Ago2. The single-stranded mature miRNA then acts as the core of RNA-induced silencing complex. This complex guides the miRNA to its target sequence located within the 3’-untranslated region (3’-UTR) of the target messenger RNA (mRNA). Incomplete or complete base-pairing results in degradation of the mRNA or inhibition of translation.
Fig. 1.
Formation of mature microRNA (miRNA). miRNA is transcribed from the genome (DNA) via RNA polymerase II (Pol II). The resulting pri-miRNA transcript is then cleaved via the endonuclease Drosha to create a 60–70 nucleotide long pre-miRNA. This transcript is then removed from the nucleus via exportin-5 to the cytoplasm where it is cleaved by Dicer, another endonuclease. The resulting double-stranded mature miRNA is unwound by a helicase or cleaved by Ago2. The single-stranded mature miRNA then acts as the core of RNA-induced silencing complex. This complex guides the miRNA to its target sequence located within the 3’-untranslated region (3’-UTR) of the target messenger RNA (mRNA). Incomplete or complete base-pairing results in degradation of the mRNA or inhibition of translation.
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Expressional Changes of miRNAs after Noxious Stimulation
Changes in the expression of miRNAs in response to noxious stimulation have been reported. Bai et al.13  reported a significant down-regulation of mature miR-10a, -29a, -98, -99a, -124a, -134, and -183 in the mandibular division of trigeminal ganglion ipsilateral to complete Freund’s adjuvant (CFA)–injected rat masseter muscle in a model of peripheral inflammation (table 1). Such down-regulated miRNAs were observed 4 h after injection and recovered differentially to a normal level or higher than normal level.13  Expression and down-regulation of miRNAs occurred in all sizes of trigeminal ganglion neurons (but not in glial cells and other nonneuronal cells) that innervate the inflamed muscle although the miRNA signals varied among neurons (table 1).13  Injection of CFA into a hind paw also reduced expression levels of miR-1, -16, -206, and -143 in the ipsilateral DRG neurons,25,26  but increased miR-1, -16, and -206 levels in the ipsilateral spinal dorsal horn neurons (table 1).25  These changes clearly correlate to CFA-induced peripheral inflammation. It should be noted that CFA-induced changes in miRNAs may be immune related as CFA also causes immune response. Interestingly, peripheral injection of formalin led to a significant down-regulation of miRNA-124a expression in the neurons of dorsal horn ipsilateral to injection (table 1).27  These studies provide promising evidence of miRNA changes in pain-related regions under inflammatory conditions.
Table 1.
miRNAs Associated with Peripheral Inflammation
miRNAs Associated with Peripheral Inflammation×
miRNAs Associated with Peripheral Inflammation
Table 1.
miRNAs Associated with Peripheral Inflammation
miRNAs Associated with Peripheral Inflammation×
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In addition to peripheral inflammation, expressional changes of miRNAs were observed after peripheral nerve injury. L5 spinal nerve ligation (SNL) induced a drastic decrease in the expression of miR-1, -7a, -96, -103, -182, -183, and -206 in the injured DRG14,25,28,29  and in the expression of miR-200b and -429 in the nucleus accumbens (table 2).30  L5 SNL also down-regulated the expression of 59 miRNAs in the uninjured L4 DRG (table 2).31  Consistently, in the sciatic nerve transection or chronic constriction injury model of neuropathic pain, the injured DRG showed reduced expression of several miRNAs, including miR-10a, -30b, -99a, -100, -143, -582-3p, and -720 (table 2).26,32  In contrast, miR-21 in the injured DRG was up-regulated after L5 SNL (table 2).14,15  Although these changes in expression may not be ruled out to be related to regeneration, the evidence indicates that the expression of miRNAs is differentially and spatially regulated in pain-related regions after peripheral nerve injury.
Table 2.
Noncoding RNAs Associated with Peripheral Nerve Injury
Noncoding RNAs Associated with Peripheral Nerve Injury×
Noncoding RNAs Associated with Peripheral Nerve Injury
Table 2.
Noncoding RNAs Associated with Peripheral Nerve Injury
Noncoding RNAs Associated with Peripheral Nerve Injury×
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Furthermore, expressional changes of miRNAs have also been observed in patients with painful diseases. In bladder biopsies from patients with bladder pain syndrome (also known as interstitial cystitis), 31 miRNAs were differentially expressed (table 1).33  An inverse relation was observed in which neurokinin-1 mRNA/protein was down-regulated and four miRNAs (miR-449b, -500, -328, and -320) were up-regulated.33  Differential expression of 18 miRNAs was reported in blood from patients with complex regional pain syndrome (table 1).34  In addition, miR-146a, -199a, and -558 may be linked to pain-related pathophysiology of osteoarthritis through regulation of the expression of cyclooxygenase-2 (table 1).35–37  It seems that miRNA profiles have the potential to serve as biomarkers of pain.
miRNAs Regulated by Inflammatory Mediators in Chronic Pain
How peripheral noxious stimulation causes the alternations of miRNA expression in pain-related regions is incompletely understood, but it is very likely that miRNA expression may be controlled by inflammatory mediators (fig. 2). Administration of resolvin D1, an anti-inflammatory lipid mediator, counter-regulated the expression of miR-21, -142, -146b, -203, -208a, -219, and -302d in a murine peritonitis model of self-limiting acute inflammation (table 1),38  suggesting at least partial involvement of inflammatory mediators in inflammation-induced changes in miRNA expression. A recent study revealed that stimulation with interleukin (IL)-1β, an inflammatory mediator, produced a significant reduction in miR-558 in normal and osteoarthritis chondrocytes possibly through IL-1β–induced activation of mitogen-activated protein kinase and nuclear factor-κB (table 1).37  IL-1β also increased the expression of miR-21 in DRG neurons,15  the insulinoma cell line MIN6,39  and human pancreatic islets.39  Activator protein 1 (AP-1), a transcription factor, may participate in this effect of IL-1β as the promoter region of miR-21 contains the binding site of AP-1,40  and IL-1β triggers AP-1 activation in DRG neurons.15  Given that peripheral inflammation and nerve injury increase DRG IL-1β expression, IL-1β may be responsible for inflammation-induced down-regulation of miR-558 and nerve injury–induced up-regulation of miR-21 in the injured DRG (fig. 2).15,37 
Fig. 2.
Proposed model for the mechanism by which microRNAs (miRNAs) contribute to chronic inflammatory and neuropathic pain. After peripheral inflammation or nerve injury, the increase in inflammatory mediators such as interleukin (IL)-1β causes a change in the expression of miRNAs in dorsal root ganglion (DRG) neurons. This change includes up-regulation of some miRNAs (e.g., miR-7a) and down-regulation of other miRNAs (e.g., miR-21), resulting in an alteration in pain-related genes, such as an increase in β-subunit of voltage-gated sodium channels (Nav), in DRG. Such an alteration leads to an increase in DRG neuronal excitability, spinal central sensitization, and pain hypersensitivity (hyperalgesia and allodynia).
Proposed model for the mechanism by which microRNAs (miRNAs) contribute to chronic inflammatory and neuropathic pain. After peripheral inflammation or nerve injury, the increase in inflammatory mediators such as interleukin (IL)-1β causes a change in the expression of miRNAs in dorsal root ganglion (DRG) neurons. This change includes up-regulation of some miRNAs (e.g., miR-7a) and down-regulation of other miRNAs (e.g., miR-21), resulting in an alteration in pain-related genes, such as an increase in β-subunit of voltage-gated sodium channels (Nav), in DRG. Such an alteration leads to an increase in DRG neuronal excitability, spinal central sensitization, and pain hypersensitivity (hyperalgesia and allodynia).
Fig. 2.
Proposed model for the mechanism by which microRNAs (miRNAs) contribute to chronic inflammatory and neuropathic pain. After peripheral inflammation or nerve injury, the increase in inflammatory mediators such as interleukin (IL)-1β causes a change in the expression of miRNAs in dorsal root ganglion (DRG) neurons. This change includes up-regulation of some miRNAs (e.g., miR-7a) and down-regulation of other miRNAs (e.g., miR-21), resulting in an alteration in pain-related genes, such as an increase in β-subunit of voltage-gated sodium channels (Nav), in DRG. Such an alteration leads to an increase in DRG neuronal excitability, spinal central sensitization, and pain hypersensitivity (hyperalgesia and allodynia).
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Potential Mechanisms of miRNAs’ Effects on Chronic Pain
It has been demonstrated that miRNAs exert their functions through their complete or incomplete sequence homology to the 3’-untranslated region of target mRNAs, resulting in a block in translation or mRNA degradation (fig. 1).23  Studies on inflammatory pain suggest that miRNAs specifically target pain-related genes (fig. 2). When a miRNA-124a inhibitor was intravenously administered after formalin injection, the down-regulation of miR-124a in the spinal cord was enhanced. This resulted in exaggerated formalin-induced nociceptive behaviors associated with an up-regulation of the pain-relevant miRNA-124a target methyl CpG-binding protein 2 and proinflammatory marker genes in the spinal cord.27  In contrast, blocking formalin-induced down-regulation of spinal cord miRNA-124a through pre-miRNA-124a administration counteracted these effects and reduced nociception by down-regulating these target genes.27  miRNA-181a possesses multiple complementary binding sites for the γ-aminobutyric acid (GABA)A receptor subunit GABAAα-1 gene, GABRA1, suggesting a possible target for this miRNA. A neonatally zymosan-induced increase in miR-181a resulted in down-regulation of the GABAAα-1 mRNA and protein in the spinal cord.41  This effect may contribute to neonatal cystitis-induced chronic visceral pain.41  Identification of the target genes of miRNAs with specific changes in chronic pain may provide insight into the role of miRNAs in chronic pain development and maintenance.
The importance of miRNAs in pain is further validated in a study in which the activity of Dicer, a key enzyme in mature miRNA formation (fig. 1), is eliminated.23  Conditional knockout of Dicer in DRG Nav1.8 neurons resulted in not only the loss of all mature miRNAs but also the reduced pain-related transcripts including voltage sodium channel (Nav) 1.7, Nav1.8, and Ca2+/calmodulin-dependent protein kinase II in the primary sensory neurons.42  The conditional null mice failed to display inflammatory mediator-induced enhancement in excitability of Nav1.8 sensory neurons and formalin-induced c-FOS expression in spinal cord.42  These mice also exhibited significant inhibition of inflammatory pain after formalin, CFA, and carrageenan injection.42  In contrast, Dicer null mice displayed an intact acute nociceptive behavior in response to electrical, mechanical, and thermal stimuli,42  indicating that the loss of mature miRNAs in the nociceptors does not affect acute pain transmission to the spinal cord and brain. Therefore, miRNAs may be potential targets for the prevention and/or treatment of chronic inflammatory pain.
The functional role of miRNAs in neuropathic pain has also been observed (fig. 2). Although Dicer null mice exhibited intact SNL-induced pain hypersensitivity,42  the role of miRNAs in neuropathic pain cannot be ruled out as deletion of DRG Nav1.8 or most DRG nociceptors had no effect on neuropathic pain.43–45  Moreover, nerve injury–induced increases in abnormal ectopic discharges were found primarily in injured myelinated afferents and the corresponding large and medium DRG neurons.46,47  Thus, miRNAs expressed in large and medium DRG neurons may be involved in the production of abnormal spontaneous activity and neuropathic pain initiation. Indeed, miR-7a is expressed in small, medium, and large DRG neurons and robustly decreased in the injured DRG in the late phase of neuropathic pain14  (table 2). Blocking this decrease through miR-7a overexpression in the injured DRG suppressed up-regulation of the β2 subunit protein of voltage-gated sodium channels in the DRG, normalized long-lasting hyperexcitability in nociceptive neurons, and attenuated established neuropathic pain without affecting acute pain and inflammatory pain.14  Furthermore, mimicking nerve injury–induced down-regulation of DRG miR-7a through intrathecal administration of a specific miR-7a inhibitor increased β2 subunit protein levels in the DRG and led to pain-related behaviors in intact rats.14  Another miRNA, miR-21, is persistently up-regulated in the injured DRG neurons during the late phase of neuropathic pain15  (table 2). The intrathecal administration of a miR-21 inhibitor (a single-stranded RNA with chemical modifications) alleviated nerve injury–induced mechanical and thermal hyperalgesia.15  miR-21 may participate in neuropathic pain conditions by down-regulating multiple targets including negative regulators of matrix metalloproteinases (which exhibit increased activity after nerve injury),48  an endogenous inhibitor of phosphatidylinositol 3-kinase (that is decreased after nerve injury),49  and negative regulators of extracellular signal–regulated kinase.50  miRNAs may also be therapeutic targets for intractable chronic neuropathic pain.
Taken together, it is very likely that inflammatory mediators produced by peripheral inflammation or nerve injury act on peripheral nociceptors and then change the expression of DRG miRNAs. These changes may alter pain-related gene expression and lead to an increase in neuronal excitability in DRG, resulting in spinal cord central sensitization and pain hypersensitivity in response to peripheral stimulation (fig. 2).
Native Kcna2 AS RNA in Chronic Neuropathic Pain
Identification of Native Kcna2 AS RNA and Its Expression in DRG
Long ncRNAs include AS RNA, double-stranded RNA, and long RNA species. Unlike the study of miRNAs, the study of long ncRNAs is still in its infancy. Although long ncRNAs may be implicated in gene-regulatory roles such as chromosome dosage compensation, imprinting, epigenetic regulation, cell cycle control, nuclear and cytoplasmic trafficking, transcription, translation, splicing, and cell differentiation,7,51,52  most long ncRNAs remain uncharacterized and their biological significance underestimated.7,52,53  We recently identified a new native RNA that is 2.52 kb in size and contains no apparent open reading frame,16,54  indicating that it is a long ncRNA. We named it Kcna2 AS RNA because most of its sequence is complementary to the voltage-gated K+ channel Kcna2 RNA (also known as Kv1.2 RNA). This AS RNA seems to be transcribed from the opposing DNA strands of the Kcna2 RNA gene at the same genomic locus.
Under normal conditions, Kcna2 AS RNA was expressed in pain-related areas, including DRG, from rats, although the signals were weak. It is also observed in DRGs from mouse, monkey, and human specimens.16  Using in situ hybridization histochemistry, we found that Kcna2 AS RNA was detected exclusively in DRG neurons. Approximately one fifth of neurons are labeled in the DRG of normal rats. Most are medium-sized although some are small and a few are large.16  Consistent with this subpopulation distribution pattern, the double-labeling observations showed that the majority of Kcna2 AS RNA–labeled neurons are positive for neurofilament-200 protein, a marker for myelinated A-fibers and large and medium DRG neurons. Some were positive for P2X3/isolectin B4, the markers for small DRG nonpeptidergic neurons, or for calcitonin gene–related peptide, a marker for small DRG peptidergic neurons. Compared with Kcna2 AS RNA, Kcna2 mRNA and protein are highly expressed in DRG. Approximately 70% of the DRG neurons were positive for Kcna2 protein.16,54,55  Most of these positive neurons were large in size.16,54,55  Double labeling of Kcna2 AS RNA with Kcna2 protein showed a tiny overlap between them.16  It seems that Kcna2 AS RNA and Kcna2 protein have opposing expression and distinct subpopulation distribution in normal DRG neurons.
Myeloid Zinc Finger Gene 1–Mediated Increase of Kcna2 AS RNA after Nerve Injury
The data from our laboratory16,54  and those of others55–60  revealed that peripheral nerve injury time-dependently down-regulated Kcna2 mRNA and protein in the injured DRG. In contrast, the level of Kcna2 AS RNA was time-dependently increased in the injured DRG after peripheral nerve injury (fig. 3).16,54  Such an increase occurred predominantly in large DRG neurons. No changes in the amount of Kcna2 AS RNA were observed in intact DRG, spinal cord, and other pain-related brain regions. Furthermore, using single-cell quantitative reverse-transcription polymerase chain reaction, we demonstrated that the ratios of Kcna2 mRNA to Kcna2 AS RNA were decreased, particularly in individual medium and large DRG neurons after SNL (fig. 3).16  These results indicate that expression of Kcna2 AS RNA, like that of miRNAs, can be induced in the injured DRG after peripheral nerve injury (table 2).
Fig. 3.
Kcna2 antisense (AS) RNA up-regulation specifically and selectively targets Kcna2 expression in neuropathic pain. (A) Under normal conditions, due to highly low expression of Kcna2 AS RNA, Kcna2 messenger RNA (mRNA) that is transcribed from the genome is translated into protein, resulting in the expression of the Kcna2 channel at the cell membrane. (B) Under neuropathic pain conditions, peripheral nerve injury promotes the expression of Kcna2 AS RNA that is transcribed from the opposing strand of the Kcna2 gene. Increased expression of Kcna2 AS RNA specifically and selectively inhibits expression of Kcna2 mRNA via extensive overlap of their complementary regions, including the transcription and translation inhibition sites, leading to reduced expression levels of the membrane Kcna2 channel only, not other Kcna family members (e.g., Kcna1).
Kcna2 antisense (AS) RNA up-regulation specifically and selectively targets Kcna2 expression in neuropathic pain. (A) Under normal conditions, due to highly low expression of Kcna2 AS RNA, Kcna2 messenger RNA (mRNA) that is transcribed from the genome is translated into protein, resulting in the expression of the Kcna2 channel at the cell membrane. (B) Under neuropathic pain conditions, peripheral nerve injury promotes the expression of Kcna2 AS RNA that is transcribed from the opposing strand of the Kcna2 gene. Increased expression of Kcna2 AS RNA specifically and selectively inhibits expression of Kcna2 mRNA via extensive overlap of their complementary regions, including the transcription and translation inhibition sites, leading to reduced expression levels of the membrane Kcna2 channel only, not other Kcna family members (e.g., Kcna1).
Fig. 3.
Kcna2 antisense (AS) RNA up-regulation specifically and selectively targets Kcna2 expression in neuropathic pain. (A) Under normal conditions, due to highly low expression of Kcna2 AS RNA, Kcna2 messenger RNA (mRNA) that is transcribed from the genome is translated into protein, resulting in the expression of the Kcna2 channel at the cell membrane. (B) Under neuropathic pain conditions, peripheral nerve injury promotes the expression of Kcna2 AS RNA that is transcribed from the opposing strand of the Kcna2 gene. Increased expression of Kcna2 AS RNA specifically and selectively inhibits expression of Kcna2 mRNA via extensive overlap of their complementary regions, including the transcription and translation inhibition sites, leading to reduced expression levels of the membrane Kcna2 channel only, not other Kcna family members (e.g., Kcna1).
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Nerve injury–induced up-regulation of Kcna2 AS RNA is triggered by myeloid zinc finger gene 1 (MZF1), a transcription factor belonging to the family of zinc finger proteins. The Kcna2 AS gene promoter contains the consensus MZF1-binding motif. Once bound to this motif, MZF1 promotes transcription of target genes.61,62  We found that MZF1 binds to this motif on the Kcna2 AS gene promoter in the DRG,16  and SNL time-dependently increases MZF1 expression and its binding activity in the injured DRG.16  Moreover, MZF1 directly promotes Kcna2 AS gene transcription and is coexpressed with Kcna2 AS RNA in DRG neurons.16  It is very likely that nerve injury–induced up-regulation of DRG Kcna2 AS RNA occurs specifically in response to the increased MZF1. It is worth noting that the increase in Kcna2 AS RNA might be induced by other transcription factors and/or caused by increases in RNA stability and other epigenetic modifications. These possibilities will be addressed in future studies.
Kcna2 RNA Specifically and Selectively Targeted by Kcna2 AS RNA
Nerve injury–induced opposing changes in the expression of Kcna2 AS RNA and Kcna2 mRNA/protein in individual DRG neurons suggest that the increased Kcna2 AS RNA may be responsible for the decreased Kcna2 mRNA and protein under neuropathic pain conditions (fig. 3). Consistent with this speculation, overexpression of full-length Kcna2 AS RNA in cultured HEK-293T cells or in cultured DRG neurons markedly knocked down Kcna2 mRNA, but not Kcna1 mRNA, Kcna4 mRNA, Scn10a (Nav1.8), and their proteins.16  In in vivo experiments, Kcna2 AS RNA overexpression time-dependently reduced Kcna2 mRNA in the DRG.16  No changes were observed in the expression of Kcna1, Kcna4, and Scn10a at the levels of mRNA and protein in the DRGs injected with AAV-Kcna2 AS RNA.16  These results suggest that nerve injury–induced DRG Kcna2 down-regulation is likely caused by a nerve injury–induced increase in DRG Kcna2 AS RNA (fig. 3). Kcna2 AS RNA functions as a biologically active regulator of Kcna2 mRNA and specifically and selectively targets Kcna2 in primary sensory neurons in neuropathic pain. This effect may be related to the extensive overlap of their complementary regions, including the transcription and translation initiation sites (fig. 3).16 
DRG Kcna2 AS RNA as a Trigger in Neuropathic Pain Genesis
Although the detailed mechanisms by which nerve injury leads to neuropathic pain are still elusive, it is generally believed that neuropathic pain is induced by abnormal spontaneous activity that arises in neuromas and the medium and large DRG cell bodies.1–3  Voltage-dependent potassium channels (Kv) govern cell excitability. Application of Kv antagonists to sensory axons and to sites of ectopic afferent discharge facilitates ectopic firing.63–66  Injection of these antagonists into nerve-end neuromas provokes intense pain in humans.67  We found that selective reduction of Kcna2 expression in DRG by Kcna2 AS RNA decreased total Kv current, depolarized the resting membrane potential, decreased current threshold for activation of action potentials, increased the number of action potentials in large and medium DRG neurons, and produced neuropathic pain symptoms.16  Rescuing nerve injury–induced down-regulation of DRG Kcna2 by blocking nerve injury–induced up-regulation of DRG Kcna2 AS RNA attenuated induction and maintenance of nerve injury–induced mechanical, cold, and heat pain hypersensitivities.16 
Given that nociceptive neurotransmitters and/or modulators (substance P and calcitonin gene–related peptide) in the injured myelinated fibers and in large and medium DRG neurons are dramatically increased at the early stage after nerve injury,68,69  it is conceivable that peripheral nerve injury up-regulates the expression of native Kcna2 AS RNA through activation of the MZF1 transcription factor in the injured DRG. This up-regulation silences the expression of DRG Kcna2 mRNA and protein, resulting in a decrease of total Kv current and an increase of ectopic discharge in large and medium DRG neurons. Ectopic discharge triggers the release of nociceptive transmitters and/or modulators in primary afferent terminals, leading to central sensitization in the dorsal horn and major symptoms of neuropathic pain (fig. 4). Thus, Kcna2 AS RNA may be an endogenous trigger in neuropathic pain development and maintenance. Kcna2 AS RNA may be a potential target for the prevention and/or treatment of neuropathic pain.
Fig. 4.
Proposed model for the mechanism of how Kcna2 AS RNA is involved in neuropathic pain. Nerve injury leads to an increase in myeloid zinc finger gene 1 (MZF1), a transcription factor that enhances the transcription of Kcna2 AS RNA, in dorsal root ganglion (DRG). The Kcan2 AS RNA silences expression of the Kcna2 messenger RNA (mRNA) and protein. The reduced Kcna2 protein expression at DRG neuronal membrane results in reduced K+ current (Kv), increases number of action potentials (AP) and neuronal excitability in DRG neurons, and produces spinal cord central sensitization and neuropathic pain symptoms (hyperalgesia and allodynia).
Proposed model for the mechanism of how Kcna2 AS RNA is involved in neuropathic pain. Nerve injury leads to an increase in myeloid zinc finger gene 1 (MZF1), a transcription factor that enhances the transcription of Kcna2 AS RNA, in dorsal root ganglion (DRG). The Kcan2 AS RNA silences expression of the Kcna2 messenger RNA (mRNA) and protein. The reduced Kcna2 protein expression at DRG neuronal membrane results in reduced K+ current (Kv), increases number of action potentials (AP) and neuronal excitability in DRG neurons, and produces spinal cord central sensitization and neuropathic pain symptoms (hyperalgesia and allodynia).
Fig. 4.
Proposed model for the mechanism of how Kcna2 AS RNA is involved in neuropathic pain. Nerve injury leads to an increase in myeloid zinc finger gene 1 (MZF1), a transcription factor that enhances the transcription of Kcna2 AS RNA, in dorsal root ganglion (DRG). The Kcan2 AS RNA silences expression of the Kcna2 messenger RNA (mRNA) and protein. The reduced Kcna2 protein expression at DRG neuronal membrane results in reduced K+ current (Kv), increases number of action potentials (AP) and neuronal excitability in DRG neurons, and produces spinal cord central sensitization and neuropathic pain symptoms (hyperalgesia and allodynia).
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Conclusion
The lines of evidence described above indicate that ncRNAs including miRNAs and Kcna2 AS RNA in peripheral and central nervous systems are endogenous instigators of chronic pain. miRNAs have been extensively studied in the past decade and may be used as prognostic and diagnostic biomarkers and potential new drug targets for chronic inflammatory pain and neuropathic pain17,18 ; however, miRNAs have multiple and specific downstream targets due to their small size.48–50  This characterization may result in the limited use of miRNAs in chronic pain treatment because they might interfere with other physiological functions and produce potential side effects. Compared with the previous reviews on miRNAs in pain processing,17,18  this review updates current knowledge on miRNAs in chronic pain. More importantly, this review summarizes the latest finding on a long ncRNA Kcna2 AS RNA in chronic pain,16,54  which has not been discussed in previous reviews.17,18  Although the studies on long ncRNAs are still at the early stage, accumulating evidence indicates that they specifically and selectively target their corresponding gene’s expression.16,54  As peripheral inflammation and nerve injury alter the expression of many other genes in addition to Kcna2 in pain-related regions,1–3  it is very likely that those genes, like Kcna2, are regulated by a corresponding long ncRNAs. Significant regulations of long ncRNA transcription may be a general cellular response to peripheral inflammation and nerve injury and participate in the induction and maintenance of chronic pain. Given that long ncRNAs have the characterization of specifically and selectively targeting the corresponding genes, it is conceivable that the significance of long ncRNAs in chronic pain will become even more apparent in the coming years.
Acknowledgments
This work was supported by grants from the National Institutes of Health, Bethesda, Maryland (grant nos. NS072206, HL117684, and DA033390), and the Rita Allen Foundation, Princeton, New Jersey.
Competing Interests
The authors declare no competing interests.
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Fig. 1.
Formation of mature microRNA (miRNA). miRNA is transcribed from the genome (DNA) via RNA polymerase II (Pol II). The resulting pri-miRNA transcript is then cleaved via the endonuclease Drosha to create a 60–70 nucleotide long pre-miRNA. This transcript is then removed from the nucleus via exportin-5 to the cytoplasm where it is cleaved by Dicer, another endonuclease. The resulting double-stranded mature miRNA is unwound by a helicase or cleaved by Ago2. The single-stranded mature miRNA then acts as the core of RNA-induced silencing complex. This complex guides the miRNA to its target sequence located within the 3’-untranslated region (3’-UTR) of the target messenger RNA (mRNA). Incomplete or complete base-pairing results in degradation of the mRNA or inhibition of translation.
Formation of mature microRNA (miRNA). miRNA is transcribed from the genome (DNA) via RNA polymerase II (Pol II). The resulting pri-miRNA transcript is then cleaved via the endonuclease Drosha to create a 60–70 nucleotide long pre-miRNA. This transcript is then removed from the nucleus via exportin-5 to the cytoplasm where it is cleaved by Dicer, another endonuclease. The resulting double-stranded mature miRNA is unwound by a helicase or cleaved by Ago2. The single-stranded mature miRNA then acts as the core of RNA-induced silencing complex. This complex guides the miRNA to its target sequence located within the 3’-untranslated region (3’-UTR) of the target messenger RNA (mRNA). Incomplete or complete base-pairing results in degradation of the mRNA or inhibition of translation.
Fig. 1.
Formation of mature microRNA (miRNA). miRNA is transcribed from the genome (DNA) via RNA polymerase II (Pol II). The resulting pri-miRNA transcript is then cleaved via the endonuclease Drosha to create a 60–70 nucleotide long pre-miRNA. This transcript is then removed from the nucleus via exportin-5 to the cytoplasm where it is cleaved by Dicer, another endonuclease. The resulting double-stranded mature miRNA is unwound by a helicase or cleaved by Ago2. The single-stranded mature miRNA then acts as the core of RNA-induced silencing complex. This complex guides the miRNA to its target sequence located within the 3’-untranslated region (3’-UTR) of the target messenger RNA (mRNA). Incomplete or complete base-pairing results in degradation of the mRNA or inhibition of translation.
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Fig. 2.
Proposed model for the mechanism by which microRNAs (miRNAs) contribute to chronic inflammatory and neuropathic pain. After peripheral inflammation or nerve injury, the increase in inflammatory mediators such as interleukin (IL)-1β causes a change in the expression of miRNAs in dorsal root ganglion (DRG) neurons. This change includes up-regulation of some miRNAs (e.g., miR-7a) and down-regulation of other miRNAs (e.g., miR-21), resulting in an alteration in pain-related genes, such as an increase in β-subunit of voltage-gated sodium channels (Nav), in DRG. Such an alteration leads to an increase in DRG neuronal excitability, spinal central sensitization, and pain hypersensitivity (hyperalgesia and allodynia).
Proposed model for the mechanism by which microRNAs (miRNAs) contribute to chronic inflammatory and neuropathic pain. After peripheral inflammation or nerve injury, the increase in inflammatory mediators such as interleukin (IL)-1β causes a change in the expression of miRNAs in dorsal root ganglion (DRG) neurons. This change includes up-regulation of some miRNAs (e.g., miR-7a) and down-regulation of other miRNAs (e.g., miR-21), resulting in an alteration in pain-related genes, such as an increase in β-subunit of voltage-gated sodium channels (Nav), in DRG. Such an alteration leads to an increase in DRG neuronal excitability, spinal central sensitization, and pain hypersensitivity (hyperalgesia and allodynia).
Fig. 2.
Proposed model for the mechanism by which microRNAs (miRNAs) contribute to chronic inflammatory and neuropathic pain. After peripheral inflammation or nerve injury, the increase in inflammatory mediators such as interleukin (IL)-1β causes a change in the expression of miRNAs in dorsal root ganglion (DRG) neurons. This change includes up-regulation of some miRNAs (e.g., miR-7a) and down-regulation of other miRNAs (e.g., miR-21), resulting in an alteration in pain-related genes, such as an increase in β-subunit of voltage-gated sodium channels (Nav), in DRG. Such an alteration leads to an increase in DRG neuronal excitability, spinal central sensitization, and pain hypersensitivity (hyperalgesia and allodynia).
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Fig. 3.
Kcna2 antisense (AS) RNA up-regulation specifically and selectively targets Kcna2 expression in neuropathic pain. (A) Under normal conditions, due to highly low expression of Kcna2 AS RNA, Kcna2 messenger RNA (mRNA) that is transcribed from the genome is translated into protein, resulting in the expression of the Kcna2 channel at the cell membrane. (B) Under neuropathic pain conditions, peripheral nerve injury promotes the expression of Kcna2 AS RNA that is transcribed from the opposing strand of the Kcna2 gene. Increased expression of Kcna2 AS RNA specifically and selectively inhibits expression of Kcna2 mRNA via extensive overlap of their complementary regions, including the transcription and translation inhibition sites, leading to reduced expression levels of the membrane Kcna2 channel only, not other Kcna family members (e.g., Kcna1).
Kcna2 antisense (AS) RNA up-regulation specifically and selectively targets Kcna2 expression in neuropathic pain. (A) Under normal conditions, due to highly low expression of Kcna2 AS RNA, Kcna2 messenger RNA (mRNA) that is transcribed from the genome is translated into protein, resulting in the expression of the Kcna2 channel at the cell membrane. (B) Under neuropathic pain conditions, peripheral nerve injury promotes the expression of Kcna2 AS RNA that is transcribed from the opposing strand of the Kcna2 gene. Increased expression of Kcna2 AS RNA specifically and selectively inhibits expression of Kcna2 mRNA via extensive overlap of their complementary regions, including the transcription and translation inhibition sites, leading to reduced expression levels of the membrane Kcna2 channel only, not other Kcna family members (e.g., Kcna1).
Fig. 3.
Kcna2 antisense (AS) RNA up-regulation specifically and selectively targets Kcna2 expression in neuropathic pain. (A) Under normal conditions, due to highly low expression of Kcna2 AS RNA, Kcna2 messenger RNA (mRNA) that is transcribed from the genome is translated into protein, resulting in the expression of the Kcna2 channel at the cell membrane. (B) Under neuropathic pain conditions, peripheral nerve injury promotes the expression of Kcna2 AS RNA that is transcribed from the opposing strand of the Kcna2 gene. Increased expression of Kcna2 AS RNA specifically and selectively inhibits expression of Kcna2 mRNA via extensive overlap of their complementary regions, including the transcription and translation inhibition sites, leading to reduced expression levels of the membrane Kcna2 channel only, not other Kcna family members (e.g., Kcna1).
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Fig. 4.
Proposed model for the mechanism of how Kcna2 AS RNA is involved in neuropathic pain. Nerve injury leads to an increase in myeloid zinc finger gene 1 (MZF1), a transcription factor that enhances the transcription of Kcna2 AS RNA, in dorsal root ganglion (DRG). The Kcan2 AS RNA silences expression of the Kcna2 messenger RNA (mRNA) and protein. The reduced Kcna2 protein expression at DRG neuronal membrane results in reduced K+ current (Kv), increases number of action potentials (AP) and neuronal excitability in DRG neurons, and produces spinal cord central sensitization and neuropathic pain symptoms (hyperalgesia and allodynia).
Proposed model for the mechanism of how Kcna2 AS RNA is involved in neuropathic pain. Nerve injury leads to an increase in myeloid zinc finger gene 1 (MZF1), a transcription factor that enhances the transcription of Kcna2 AS RNA, in dorsal root ganglion (DRG). The Kcan2 AS RNA silences expression of the Kcna2 messenger RNA (mRNA) and protein. The reduced Kcna2 protein expression at DRG neuronal membrane results in reduced K+ current (Kv), increases number of action potentials (AP) and neuronal excitability in DRG neurons, and produces spinal cord central sensitization and neuropathic pain symptoms (hyperalgesia and allodynia).
Fig. 4.
Proposed model for the mechanism of how Kcna2 AS RNA is involved in neuropathic pain. Nerve injury leads to an increase in myeloid zinc finger gene 1 (MZF1), a transcription factor that enhances the transcription of Kcna2 AS RNA, in dorsal root ganglion (DRG). The Kcan2 AS RNA silences expression of the Kcna2 messenger RNA (mRNA) and protein. The reduced Kcna2 protein expression at DRG neuronal membrane results in reduced K+ current (Kv), increases number of action potentials (AP) and neuronal excitability in DRG neurons, and produces spinal cord central sensitization and neuropathic pain symptoms (hyperalgesia and allodynia).
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Table 1.
miRNAs Associated with Peripheral Inflammation
miRNAs Associated with Peripheral Inflammation×
miRNAs Associated with Peripheral Inflammation
Table 1.
miRNAs Associated with Peripheral Inflammation
miRNAs Associated with Peripheral Inflammation×
×
Table 2.
Noncoding RNAs Associated with Peripheral Nerve Injury
Noncoding RNAs Associated with Peripheral Nerve Injury×
Noncoding RNAs Associated with Peripheral Nerve Injury
Table 2.
Noncoding RNAs Associated with Peripheral Nerve Injury
Noncoding RNAs Associated with Peripheral Nerve Injury×
×