3rd Prize: Yi (Daniel) Zhou

Elucidating the role of endogenous opioids in the regulation of social pain  

by  Yi (Daniel) Zhou
(Supervisor:Dr. Gustavo Turecki)

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The perception of pain is but one component of an emotional system which can regulate simple behaviors, such as a recoiling reflex, to convoluted neurotic behaviors characterizing severe mental health disorders. Although the perception of physical pain is crucial for navigating our physical world, the perception of social pain is equally as important, at the very least, for human survival.

Anyone who has lived long enough in this world can tell you just how painful a broken heart is or how painful it is to experience loss. These forms of social pain are thought to result from the same emotional system that regulates the affective component of pain perception, that is, the emotional feeling of unpleasantness usually associated with physical pain [1]. Historical descriptions of patients who had undergone cingulumotomy for the treatment of chronic pain reported how they were aware of, and able to, localize pain sensations but felt no distress or suffering [2]. In other words, they seemed to lack an emotional reactivity to painful stimuli after the surgery.  In later studies, the brain regions regulating the experience of social pain were shown to also include the anterior cingulate cortex (ACC) as well as the anterior insula (AI) and dorsal medial thalamus (DMT). For example, in humans, imaging studies have shown that situations of social exclusion, which increases social distress, were correlated with increased brain activity in the ACC and AI [3].

As it is clear that the perception of social pain plays a large role in how we experience the world, I believe dysfunctions in this emotional system will result in serious consequences to human health and well-being.  Specifically, I have worked in the lab of Dr. Gustavo Turecki at the McGill Group for Suicide Studies (MGSS) to investigate the role of the opioid system in the regulation of social pain and whether the maladaptive development of the opioid system may be an underlying contributor to the etiology of suicide.

It is well known that opiates regulate physical pain perception; exogenous opioids such as morphine are used as potent analgesics. Interestingly, the mu opioid receptor (the main receptor responsible for analgesic functions of some endogenous and exogenous opiates) is highly expressed in both the ACC and AI [4]. Animal studies show that opiate administration reduces separation distress, such as distress vocalizations elicited upon maternal separation [5]. Additionally, mice lacking the mu opioid receptor show significant reductions in attachment behaviors, such as distress vocalizations after maternal separation, presumably because knockout mice show blunted sensitivity to painful social experiences [6]. Finally, it is well known that heroin, a derivative of morphine, is a notorious drug of abuse that produces analgesic, euphoric, and anxiolytic effects associated with the regulation of physical and social pain [7].  Importantly, social attachment and social behaviors are crucial for early survival. In later life, social interactions play enormous roles in our everyday life. It has been proposed that animals and humans develop behaviors that reduce the potential social harm they may encounter [8]. However, in humans, when these behaviors get out of hand, they may become anxiety disorders. Suicide may be a means, albeit an extreme one on the continuum of detrimental behaviors, to escape such negative experiences. Suicide is not only more prevalent in patients with chronic pain, but is also more common in those suffering from social isolation and social loss [9]. As such, we hypothesized that suicide completers should show an altered expression of the opioid system compared to controls that died from causes other than suicide.

Accordingly, we quantified the expression of endogenous opioid receptor and peptide mRNA in the ACC, AI, and DMT brain regions of suicide completers and compared them to subjects who died from causes other than suicide. Specifically, I quantified the expression of the orphanin FQ, or nociceptin, opioid sub-system. Using quantitative reverse transcription polymerase chain reaction, I found that suicide completers showed a significantly reduced expression of the pre-pro-nociceptin mRNA, the transcript of the endogenous opioid peptide, in the caudal ACC (Figure. 1).

With these recent findings, new avenues for further investigation have opened up. The nociceptin opioid sub-system has been implicated in the HPA axis response to stress and in natural and learned anxiety-like behavior [10]. As the nociceptin receptor is a G-protein coupled receptor, G-protein coupled receptor assays will be done to determine whether changes in the sensitivity or functional activity of the nociceptin system have occurred in association with the observed decrease of pre-pro-nociceptin mRNA in suicide completers (Figure. 2).  Furthermore, whether the expression of the opioid system is regulated epigenetically as a function of life experiences will also be investigated. For example, one animal study has shown that severe traumatic life experiences can disrupt the ability of mice to distinguish between harmful and safe environments, reflecting an animal model for post-traumatic stress disorder (PTSD) [11]. In addition, this behavioral consequence was associated with altered nociceptin receptor expression in the amygdala of traumatized mice compared to non-traumatized ones. Interestingly, it has been proposed that the ACC and amygdala are components of an emotional fear processing system, whereby the amygdala is important for the identification of emotionally salient stimuli while the ACC is responsible for the regulation of emotion processing and related behavior [12]. Taken together, the results of our study suggest a role for the nociceptin opioid system in the regulation of social pain, which may influence the ability to learn, directed by the fear-emotional neural system.

As I believe our emotions are key tools used in directing our behaviors to avoid harmful or painful stimuli, a dysfunctional emotional system that produces inappropriate behaviors, or one that prevents the escape from these feelings of social pain, may result in suicide. With a better understanding of the neurobiological underpinnings of social pain and the systems that regulate its perception and the behaviors that arise as a result, I hope we will aid the development of effective and appropriate treatments that either reverse, or at least better manage, implicated mental illnesses.

Figure 1Levels of pre-pro-nociceptin (PNOC) mRNA expression (estimated marginal mean ± s.e.m) in the caudal ACC compared between suicide completers (N = 54) and controls (N=26) (controlled for age as a co-variate). * indicates p < 0.05.

Figure 2 – A functional assay using re-constituted membranes (produced from human brain tissues that have retained functional signaling systems) and GTPγS molecules (a radioactive, non-hydrolyzable G-protein activating analogue of guanosine triphosphate) may reveal whether the sensitivity, or activity, of the nociceptin system has changed in association with the reported decreased levels of pre-pro-nociceptin mRNA in suicide completers. (Image by John Zhou using Inkscape graphics editor)

 

Citations

 

1.         Eisenberger, N.I., The pain of social disconnection: examining the shared neural underpinnings of physical and social pain. Nat Rev Neurosci, 2012. 13(6): p. 421-34.

2.         Foltz, E.L. and L.E. White, Jr., Pain "relief" by frontal cingulumotomy. J Neurosurg, 1962. 19: p. 89-100.

3.         Eisenberger, N.I. and M.D. Lieberman, Why rejection hurts: a common neural alarm system for physical and social pain. Trends Cogn Sci, 2004. 8(7): p. 294-300.

4.         Jones, A.K., et al., In vivo distribution of opioid receptors in man in relation to the cortical projections of the medial and lateral pain systems measured with positron emission tomography. Neurosci Lett, 1991. 126(1): p. 25-8.

5.         Panksepp, J., et al., The biology of social attachments: opiates alleviate separation distress. Biol Psychiatry, 1978. 13(5): p. 607-18.

6.         Moles, A., B.L. Kieffer, and F.R. D'Amato, Deficit in attachment behavior in mice lacking the mu-opioid receptor gene. Science, 2004. 304(5679): p. 1983-6.

7.         Lutz, P.E. and B.L. Kieffer, The multiple facets of opioid receptor function: implications for addiction. Curr Opin Neurobiol, 2013. 23(4): p. 473-9.

8.         LeDoux, J., The Emotional Brain 1996, New York: Simon and Schuster.

9.         Mee, S., et al., Psychological pain: a review of evidence. J Psychiatr Res, 2006. 40(8): p. 680-90.

10.       Mallimo, E.M. and A.W. Kusnecov, The role of orphanin FQ/nociceptin in neuroplasticity: relationship to stress, anxiety and neuroinflammation. Front Cell Neurosci, 2013. 7: p. 173.

11.       Andero, R., et al., Amygdala-dependent fear is regulated by Oprl1 in mice and humans with PTSD. Sci Transl Med, 2013. 5(188): p. 188ra73.

12.       Hung, Y., M.L. Smith, and M.J. Taylor, Development of ACC-amygdala activations in processing unattended fear. Neuroimage, 2012. 60(1): p. 545-52.

 

 

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