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Research ArticleMinireviews

Arresting the Development of Addiction: The Role of β-Arrestin 2 in Drug Abuse

Kirsten A. Porter-Stransky and David Weinshenker
Journal of Pharmacology and Experimental Therapeutics June 2017, 361 (3) 341-348; DOI: https://doi.org/10.1124/jpet.117.240622
Kirsten A. Porter-Stransky
Department of Human Genetics, Emory University School of Medicine, Atlanta, Georgia
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David Weinshenker
Department of Human Genetics, Emory University School of Medicine, Atlanta, Georgia
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Abstract

The protein β-arrestin (βarr) 2 directly interacts with receptors and signaling pathways that mediate the behavioral effects of drugs of abuse, making it a prime candidate for therapeutic interventions. βarr2 drives desensitization and internalization of G protein–coupled receptors, including dopamine, opioid, and cannabinoid receptors, and it can also trigger G protein–independent intracellular signaling. βarr2 mediates several drug-induced behaviors, but the relationship is complex and dependent on the type of behavior (e.g., psychomotor versus reward), the class of drug (e.g., psychostimulant versus opioid), and the circuit being interrogated (e.g., brain region, cell type, and specific receptor ligand). Here we discuss the current state of research concerning the contribution of βarr2 to the psychomotor and rewarding effects of addictive drugs. Next we identify key knowledge gaps and suggest new tools and approaches needed to further elucidate the neuroanatomical substrates and neurobiological mechanisms to explain how βarr2 modulates behavioral responses to drugs of abuse, as well as its potential as a therapeutic target.

Introduction

G protein–coupled receptors (GPCRs) mediate many of the neurochemical and behavioral effects of addictive drugs. For example, most drugs of abuse increase dopamine neurotransmission in the mammalian brain, either directly or indirectly, which leads to the stimulation of dopaminergic GPCRs (Di Chiara and Imperato, 1988; Lüscher and Ungless, 2006; Pierce and Kumaresan, 2006). Some classes of drugs, such as opioids and cannabinoids, are agonists at opioid and cannabinoid receptors, respectively, which are also GPCRs. GPCR signaling is thus a critical component of drug-induced neurotransmission.

Termination of signal transduction at GPCRs is necessary to prevent continual signaling and to allow receptors to be reactivated by ligands. Arrestins, which were first discovered in photoreceptor-expressing cells in the eye (Dolph, 2002), are proteins that bind to active phosphorylated GPCRs and inactivate them (Gurevich and Gurevich, 2004). Visual arrestins are located primarily in the eye, and nonvisual arrestins, also known as β-arrestins (βarrs), are ubiquitously expressed. βarrs, so named from the discovery of their interactions with β-adrenergic receptors (Attramadal et al., 1992), are scaffolding proteins involved in the desensitization and internalization of GPCRs at the plasma membrane. They can also initiate intracellular signaling cascades independent of canonical G protein signaling (Smith and Rajagopal, 2016). GPCRs in the membrane were thought to signal until βarr desensitized and internalized them; however, recent experiments have shown that certain GPCRs can signal after being internalized by βarr into endosomes (Irannejad et al., 2013), and βarr can even potentiate Gs signaling (Wehbi et al., 2013). βarrs can interact with extracellular signal–regulated kinase (ERK), Protein kinase B, mitogen-activated protein kinase kinase, Raf-1, c-Jun N-terminal kinase, and ubiquitin ligases, to name a few (Luttrell et al., 2001; Shenoy et al., 2001; Beaulieu et al., 2005; Del’guidice et al., 2011; Urs et al., 2011; Kuhar et al., 2015). βarr can also modulate nuclear factor-κB through IκBα (Gao et al., 2004). Additional interactions and complexities of βarr continue to be discovered; therefore, the field’s understanding of βarr is constantly evolving.

Functional selectivity, also known as biased agonism, is the principle that agonists bound to a GPCR can preferentially signal through different pathways. GPCR ligands can selectively activate intracellular G protein signaling, βarr pathways, or both to varying degrees (Luttrell et al., 2015). Biased agonism complicates GPCR activity, as different agonists at the same receptor can have opposing effects on physiology (Boerrigter et al., 2012; Tarigopula et al., 2015). Ligands that preferentially engage βarr versus G protein signaling can alter responses to opioids, psychostimulants, and hallucinogens (Soergel et al., 2014; Peterson et al., 2015; Manglik et al., 2016; Urs et al., 2016); therefore, biased agonists could be potential therapeutics for addiction, analgesia, and other conditions.

There are two βarrs: β-arrestin 1 (βarr1; also known as arrestin-2) and β-arrestin 2 (βarr2, also known as arrestin-3). βarr1 and βarr2 can have similar or distinct roles in cells, and their function can vary by cell type. For example, reduction of either βarr1 or βarr2 decreased β2-adrenergic induced ERK signaling (Shenoy et al., 2006). However, angiotensin II receptor–mediated ERK signaling decreased with a reduction of βarr2 but increased with downregulation of βarr1 (Ahn et al., 2004). Most class A receptors (including dopamine, opioid, and cannabinoid receptors) bind both βarr1 and βarr2; however, they have a higher affinity for βarr2 (Oakley et al., 2000), making βarr2 a likely candidate for modulating GPCR signaling and the effects of drugs of abuse.

Indeed, mice lacking βarr2 but not βarr1 have altered behavioral responses to addictive drugs, including morphine (Bohn et al., 2003; Urs and Caron, 2014), amphetamine (Urs and Caron, 2014), and alcohol (Li et al., 2013) (Table 1); therefore, βarr2 is a likely candidate for modulating the effects of drugs of abuse. The purpose of this review is to catalog what is currently known about the role of βarr2 in mediating the behavioral effects of various drugs of abuse and to discuss the questions that remain and what techniques are needed to properly answer these questions. For a more thorough review of the cellular and molecular functions of βarr2, we refer the reader to Smith and Rajagopal (2016).

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TABLE 1

The behavioral effects of drugs of abuse in mice completely lacking βarr2

βarr2 Modulates the Effects of Multiples Classes of Drugs of Abuse

Opioids.

Most of the pioneering studies that examined the role of βarr2 in the behavioral effects of drugs of abuse used conventional βarr2 knockout (KO) mice, which completely lack βarr2 in all cells throughout development and in adulthood. βarr2-KO mice have significantly blunted morphine-induced locomotion but enhanced morphine reward, as measured by conditioned place preference (CPP) (Bohn et al., 2003).

Because many psychomotor drug effects are mediated by dopamine neurotransmission in the striatum and prefrontal cortex (Pierce and Kumaresan, 2006), βarr2 is presumed to exert its effects in the mesocorticolimbic system. Indeed, βarr2-KO mice exhibit higher morphine-induced dopamine release in the striatum compared with controls (Bohn et al., 2003). βarr2 in medium spiny neurons (MSNs) that contain dopamine receptors in the dorsal and ventral striatum may also modulate the psychomotor effects of drugs. However, the relative contribution of the D1 or D2 family of dopamine receptors to the differing drug-induced behavioral effects is unknown. Determining which family of dopamine receptors mediates such effects is important because D1 and D2 receptors have opposing influences on the excitability of MSNs (Beaulieu and Gainetdinov, 2011) and are anatomically segregated onto separate populations of MSNs that project to different brain regions (Lobo and Nestler, 2011). Indeed, activation of D1- versus D2-containing MSNs causes differential changes in whole-brain activity (Lee et al., 2016) and has opposite effects on reinforcement (Kravitz et al., 2012).

βarr2 in D1-containing neurons was initially proposed as a mechanism for morphine-induced locomotion. In support of this hypothesis, morphine normally induces a βarr2/pERK signaling complex, but this did not occur in D1-KO mice (Urs et al., 2011). In addition, D1-KO mice and wild-type animals developed a similar CPP for morphine (Urs et al., 2011), demonstrating that D1 receptors are not necessary for morphine reward. To directly test the role of βarr2 in D1-containing neurons, morphine CPP and locomotion could be tested in conditional KO mice that lack βarr2 only in D1-containing cells (Urs et al., 2016). Similarly, future experiments should directly test the role of βarr2 in D2-containing neurons in mediating the effects of morphine.

While βarr2’s interactions with dopamine receptors may modulate opioid effects, µ-opioid receptor recruitment of βarr2 could also be important because morphine has a high affinity for µ-opioid receptors, which, like dopamine receptors, are expressed on striatal MSNs, among other regions. Historically, however, morphine was found to not recruit βarr2 and prompt the internalization of µ-opioid receptors as readily as many other µ-opioid receptor agonists. For example, etorphine caused robust internalization of µ-opioid receptors in the cortex of rats 30 minutes postadministration, whereas morphine caused no detectable µ-opioid receptor endocytosis (Keith et al., 1998). Similarly, previous in vitro experiments did not find morphine-induced recruitment of βarr2 or the internalization of µ-opioid receptors in human embryonic kidney cells; unless GPCR kinase was overexpressed (Zhang et al., 1998), βarr was overexpressed, or βarr1 was eliminated and only βarr2 was available (Whistler and von Zastrow, 1998). However, morphine did trigger the rapid endocytosis of µ-opioid receptors in striatal neurons (Haberstock-Debic et al., 2005). Despite morphine’s reduced ability to recruit βarr2 in some cells, βarr2 is critical for morphine’s effects. In vitro experiments using βarr2-KO, βarr1-KO, and control cells revealed that, unlike the selective µ-opioid receptor agonist DAMGO [(2S)-2-[[2-[[(2R)-2-[[(2S)-2-amino-3-(4-hydroxyphenyl)propanoyl]amino]propanoyl]amino]acetyl]-methylamino]-N-(2-hydroxyethyl)-3-phenylpropanamide], which can recruit either βarr1 or βarr2 to µ-opioid receptors, morphine appears to be able to recruit only βarr2. Indeed, βarr2 but not βarr1 internalized morphine-activated µ-opioid receptors (Groer et al., 2011). Together, these studies indicate that µ-opioid receptors recruit βarr2 in certain cell populations, such as MSNs, but not in others, and sensitive assays are needed to observe these effects. Furthermore, different opioids can elicit unique adaptations that alter how βarr2 is engaged and highlight the importance of biased agonism in understanding βarr2 recruitment.

The ability or inability of µ-opioid agonists to recruit βarr2 can have important behavioral consequences. The µ-opioid receptor agonists morphine, heroin, and oxycodone have low recruitment of βarr2 and low levels of endocytosis (Keith et al., 1998; Whistler and von Zastrow, 1998; Zhang et al., 1998); however, all three have high abuse potential and can cause tolerance and dependence. It has therefore been hypothesized that the lack of opioid-induced desensitization and internalization of µ-opioid receptors contributes to these features of addiction. To test this hypothesis, a mutant recycling µ-opioid receptor that desensitizes and internalizes in response to morphine was created (Finn and Whistler, 2001). Interestingly, although these mice had an enhanced CPP to low doses of morphine, they neither escalated morphine consumption nor exhibited aberrant motivation for drug over weeks of morphine self-administration, unlike wild-type mice, which escalated intake, continued to self-administer drug despite the threat of footshock, and had greater reinstatement of drug seeking (Berger and Whistler, 2011). These results demonstrated that µ-opioid receptor internalization has different effects on drug reward (as measured by CPP) versus the development of more complex addictive-like behaviors. Because βarr2 is recruited to morphine-activated receptors to internalize them (Groer et al., 2011), it may play an important role in preventing the transition from recreational use to addiction. Future experiments should investigate this directly.

To determine how endogenous βarr2 changes with morphine exposure, in situ hybridization was conducted on the brains of rats with a history of morphine administration. Chronic but not acute morphine exposure increased βarr2 mRNA in the cortex and decreased βarr2 mRNA in the periaqueductal gray (Fan et al., 2003). In addition, naloxone-precipitated withdrawal robustly increased βarr2 mRNA in the hippocampus (Fan et al., 2003). These experiments revealed that βarr2 can be differentially regulated in various brain regions in response to drugs. Future experiments are needed to determine the behavioral and biologic effects of changing βarr2 levels in these and other brain regions.

Consistent with the animal research indicating that βarr2 modulates drug effects, human studies have found differences in βarr2 in people susceptible to opioid abuse. Indeed, individuals who died from heroin overdose had decreased levels of βarr2 specifically in the prefrontal cortex compared with matched controls (Ferrer-Alcón et al., 2004). In addition, a haplotype block that spans the βarr2 locus has been discovered, and four single nucleotide polymorphisms (SNPs) (rs34230287, rs3786047, rs1045280, and rs2036657) have been studied in opioid-dependent humans under treatment. Those who were homozygous for the variant allele of any three of the four SNPs (all but rs34230287) were more likely to continue using opioids or cocaine while on methadone maintenance treatment (Oneda et al., 2011). This demonstrated that genetic differences in βarr2 can confer resistance to methadone treatment of opioid dependence. None of these SNPs cause changes in the amino acid sequence, and the biologic effects of each are not yet known; however, different SNPs could reduce, enhance, or have no effect on GPCRs and βarr2 signaling. Future research should investigate the physiologic effects of each of these SNPs and whether they cause changes in βarr2 expression in different brain regions.

Chronic pain is a common reason why individuals begin taking opioids, which can transition into opioid addiction; therefore, examining the role of βarr2 in opioid modulation of pain is an important consideration. Paradoxically, µ-opioid receptor agonists that readily recruit βarr2, such as fentanyl, methadone, and etorphine, caused similar analgesia in wild-type and βarr2-KO mice; however, agonists that do not robustly recruit βarr2, such as morphine and heroin, enhanced analgesia in βarr2-KOs compared with controls (Bohn et al., 1999, 2004a). Similarly, both wild-type and βarr2-KO mice developed tolerance to fentanyl, oxycodone, and methadone (Raehal and Bohn, 2011) but not to morphine after chronic administration (Bohn et al., 2002; Raehal and Bohn, 2011). Although βarr2 is not readily recruited by morphine in all cell types, it can play a critical role in desensitizing µ-opioid receptors (Bohn et al., 2002, 2004a; Groer et al., 2011).

βarr2 likely mediates many of morphine’s negative side effects. In support of this idea, βarr2-KO mice have significantly reduced morphine-induced constipation and respiratory suppression, compared with controls (Raehal et al., 2005). In addition, after screening over 3 million molecules as new potential opioids, the compound PZM21 (1-[(2S)-2-(dimethylamino)-3-(4-hydroxyphenyl)propyl]-3-[(2S)-1-(thiophen-3-yl)propan-2-yl]urea) was found to have high selectivity for the µ-opioid receptor and to strongly activate Gi signaling without engaging βarr2 (Manglik et al., 2016). Interestingly, PZM21 was an effective analgesic in the hotplate test (which engages brain and spinal pain circuits) but not in the tail-flick test (which solely engages spinal, reflexive circuits), suggesting that this novel opioid causes affective but not reflexive analgesia. Unlike morphine, which has high abuse potential, doses of PZM21 that cause analgesia did not increase locomotor active or support a CPP. Combined, these experiments demonstrate that µ-opioid receptor agonists that preferentially engage Gi, but not βarr2, signaling could be effective treatments for pain without the negative side effects and high abuse potential.

For a more comprehensive review of βarr2’s involvement in opioid-mediated analgesia, please refer to Raehal and Bohn (2014). Because βarr2 is differentially involved in the antinociceptive effects of various opioids, future experiments should test the role of βarr2 in the rewarding effects of opioids other than morphine. In addition, functionally selective agonists such as PZM21 could be used in future experiments to preferentially engage Gi signaling after µ-opioid receptor activation.

Cannabinoids.

As with morphine, cannabinoid receptor agonists can provide pain relief and are abused. Both CB1 and CB2 cannabinoid receptors recruit βarr2 (McGuinness et al., 2009; van der Lee et al., 2009; Turu and Hunyady, 2010; Delgado-Peraza et al., 2016). Most research has focused on CB1 (Daigle et al., 2008; Mahavadi et al., 2014; Delgado-Peraza et al., 2016), whereas very little is known about the potential contribution of βarr2 to the effects of CB2 activation (Atwood et al., 2012). βarr2 is involved in the behavioral effects of some but not all cannabinoid receptor agonists (Raehal and Bohn, 2014). The cannabinoid receptor agonist Δ9-tetrahydrocannabinoid caused greater antinociception in βarr2-KO mice compared with controls (Breivogel et al., 2008; Nguyen et al., 2012), but no differences between genotypes were observed for the CB1 agonists CP55940 [(−)-cis-3-[2-hydroxy-4-(1,1-dimethylheptyl)phenyl]-trans-4-(3-hydroxypropyl)cyclohexanol], methanandamide, JWH-073 [(1-butyl-1H-indol-3-yl)-1-naphthalenyl-methanone], and O-1812 [(5Z,8Z,11Z,14Z)-20-cyano-N-[(2R)-1-hydroxypropan-2-yl]-16,16-dimethylicosa-5,8,11,14-tetraenamide] (Breivogel et al., 2008). Seven-day treatment with CP55940 increased βarr2 mRNA and protein levels in the prefrontal cortex (Franklin et al., 2013), suggesting that cannabinoid agonists can upregulate βarr2.

To our knowledge, the role of βarr2 in the rewarding effects of cannabinoids has yet to be examined. Because of the growing use and legalization of marijuana, future experiments should examine the role of βarr2 in modulating cannabinoid reinforcement and use.

Psychostimulants.

The first published experiments examining the role of βarr2 in behavioral responses to psychostimulants were conducted using βarr2-KO mice. No robust differences in cocaine-induced locomotion, locomotor sensitization to cocaine, or cocaine CPP were documented in βarr2-KO mice compared with wild-type controls (Bohn et al., 2003). βarr2-KO mice appeared to have slightly reduced cocaine-induced locomotion; yet this is difficult to interpret, given baseline differences in locomotor activity between genotypes (Bohn et al., 2003, 2004b). However, βarr2-KO mice had significantly blunted amphetamine-induced locomotion, and this effect was not due to differences in stereotypy (Beaulieu et al., 2005). Similarly, mice lacking βarr2 in all neurons (generated by crossing floxed βarr2 mice with cytomegalovirus-Cre mice) showed impaired amphetamine-induced locomotion compared with controls (Urs et al., 2016). There are a few possible explanations as to why differences in locomotion were observed after amphetamine but not cocaine in mice lacking βarr2. If βarr2 deletion had a real but more subtle effect on cocaine-induced locomotion than amphetamine-induced locomotion, collapsing the data and analyzing 90-minute time bins could obscure the effect. In addition, it is possible that βarr1 compensates in the absence of βarr2 to facilitate cocaine- but not amphetamine-induced locomotion. Given the different ways that cocaine and amphetamine interact with the dopamine transporter (reuptake blocker versus substrate/releaser, respectively) and the regulation of dopamine transporter function by intracellular signaling (Schmitt and Reith, 2010), it is plausible that βarr2 interacts either directly or indirectly with the dopamine transporter in such a way that cocaine and amphetamine are differentially affected, although we are not aware of data to substantiate this explanation.

As detailed in the opioid section, determining whether βarr2 influences drug effects via D1- or D2-containing neurons is important due to these receptors’ opposing effects and projections to different brain regions. Eliminating βarr2 only in certain populations of neurons is possible by crossing floxed βarr2 mice with D1Cre mice (for D1-containing cells), D2Cre mice (for all D2-containing cells), A2aCre mice (for D2-containing postsynaptic striatal neurons), or ChaTCre mice (for cholinergic interneurons). Mice lacking βarr2 in striatal D2 MSNs or in all D2-containing neurons but not in D1-containing neurons or cholinergic interneurons exhibited blunted amphetamine-induced locomotion (Urs et al., 2016). These experiments demonstrated that βarr2 in D2-containing neurons, particularly in the striatum, facilitates amphetamine locomotor responses. To further probe the role of βarr2 in behavioral responses to amphetamines, viral vectors have been created to express D2 receptors with biased G protein signaling or D2 receptors with biased βArr2 signaling. Overexpressing D2 receptors with biased βarr2 but not G protein signaling in the striatum potentiated amphetamine-induced locomotion (Peterson et al., 2015), revealing a role of βarr2 signaling downstream of striatal D2 receptors. Together, these experiments demonstrated that βarr2 modulates the locomotor-activating effects of psychostimulants, likely through βarr2 signaling in D2-containing cells. Future experiments should test whether this mechanism also mediates psychostimulant reward.

Mice that lack dopamine β-hydroxylase (Dbh−/− mice) cannot synthesize norepinephrine and are hypersensitive to cocaine. Interestingly, these animals had reduced βarr2 in the nucleus accumbens and altered D2 receptor function (Gaval-Cruz et al., 2016). Overexpressing βarr2 in the nucleus accumbens of Dbh−/− mice reversed the cocaine hypersensitivity (Gaval-Cruz et al., 2016), demonstrating the complex effects that βarr2 can have in cocaine-induced locomotion. These results are difficult to reconcile with the data obtained from βarr2-KO mice, which show minimal or no blunting of cocaine-induced locomotion and significantly reduced amphetamine-induced locomotion, suggesting that overexpression of βarr2 would potentiate, not reduce, cocaine-induced locomotion. One possible explanation is that Dbh−/− mice have unique neural adaptations due to their chronic, lifelong loss of norepinephrine. An alternative explanation is that βarr2 in the nucleus accumbens functions in a bimodal way, such that abnormally high or low levels of βarr2 could blunt psychostimulant responses. Finally, whether Dbh−/− mice have reduced βarr2 in D1-, D2-, or both D1- and D2-containing MSNs is currently unknown, and the ratio of βarr2 in these two cell populations could potentially influence cocaine-induced locomotion.

Alcohol.

βarr2-KO mice have been used to test the role of βarr2 in alcohol reinforcement. Whereas one study found that mice completely lacking βarr2 consumed significantly less alcohol at low doses and had a reduced preference for alcohol in a two-bottle choice procedure compared with controls (Björk et al., 2008), another laboratory observed that βarr2-KO mice consumed more alcohol, especially at higher doses (Li et al., 2013). However, both studies reported that βarr2-KO mice had enhanced CPP for low doses of alcohol (Björk et al., 2013; Li et al., 2013), possibly indicating that the lack of βarr2 conferred hypersensitivity to the rewarding properties of alcohol. βarr2-KO mice also had attenuated alcohol-induced locomotor responses compared with wild-type animals (Björk et al., 2008; Li et al., 2013).

βarr2-KO mice regained their righting reflex slightly faster than controls after a large dose of alcohol (Li et al., 2013) but had normal motor performance on a rotarod when under the influence of alcohol (Björk et al., 2008). In addition, although βarr2-KO mice had slightly reduced blood alcohol levels after a single alcohol injection, alcohol clearance rates were similar to wild-type mice (Björk et al., 2008; Li et al., 2013). Combined, these experiments indicate that the differences in behavioral response of βarr2-KO mice to alcohol probably cannot be attributed to differences in the sedative properties of ethanol or its pharmacokinetics.

A few studies have examined genetic differences in βarr2 in relation to alcohol. Two lines of rats, “alcohol-preferring” and “alcohol-avoiding,” have been bred based on their voluntary alcohol intake. Alcohol-preferring rats had elevated levels of βarr2 mRNA in the nucleus accumbens, dorsal striatum, and hippocampus, as well as higher βarr2 protein in the hippocampus compared with alcohol-avoiding rats (Björk et al., 2008). Interestingly, Björk et al. (2008) uncovered a novel haplotype variant of the βarr2 gene that completely segregated between the two lines of rats and was highly correlated with ethanol consumption, and bioinformatic analysis revealed an expression quantitative trait locus for βarr2 in the brain regions that had elevated βarr2 mRNA. This is consistent with the observation that βarr2-KO mice voluntarily consumed less alcohol (Björk et al., 2008). Higher levels of βarr2 therefore predict greater ethanol consumption, whereas eliminating βarr2 reduces ethanol intake. Although genetic differences in βarr2 correspond to ethanol intake in rodents, no association between different polymorphisms of βarr2 and alcohol dependence has been observed in humans (Oneda et al., 2010).

The reinforcing effects of alcohol are thought to be mediated by dopamine release in striatal regions as well as endogenous opioid systems. Consistent with this theory, βarr2-KO mice had enhanced alcohol-evoked dopamine release in the nucleus accumbens shell (Björk et al., 2013), which may contribute to the alcohol hypersensitivity. However, βarr2-KO mice lacked the alcohol-induced elevations in c-fos in the nucleus accumbens shell seen in control animals (Björk et al., 2008). Although µ-opioid receptor binding and function did not differ between βarr2-KO and wild-type mice in drug-naïve conditions (likely due to low levels of receptor activation), alcohol induced greater µ-opioid receptor agonist stimulation in the dorsal striatum and amygdala of βarr2-KO mice (Björk et al., 2013). These differences in µ-opioid receptor function may contribute to the altered behavioral responses to alcohol in βarr2-KO mice. The impaired desensitization and internalization of µ-opioid receptors in the absence of βarr2 may cause heightened µ-opioid receptor signaling and greater sensitivity to alcohol, as evidenced by enhanced CPP and reduced ethanol intake.

In addition to µ-opioid receptors, δ-opioid receptors can also interact with βarr2 and modulate alcohol intake. δ-opioid receptor agonists that strongly recruit βarr2 have been shown to increase ethanol intake in wild-type mice, whereas agonists with poor βarr2 recruitment dose-dependently decreased ethanol consumption (Chiang et al., 2016). Furthermore, an agonist with low βarr2 recruitment decreased ethanol intake in βarr2-KO mice, whereas an agonist that robustly recruits βarr2 neither decreased ethanol intake nor blocked the development of a CPP for alcohol in βarr2-KO mice (Chiang et al., 2016). These results indicated that the effect of low βarr2-recruiting δ-opioid receptor agonists to decrease alcohol consumption occurs through βarr2-independent mechanisms, whereas high βArr2-recruiting δ-opioid agonists require βarr2 to enhance alcohol intake. Together, this series of experiments demonstrates that the ability of Δ-opioid receptor agonists to recruit βarr2 has significant effects on alcohol intake. Examining βarr2 recruitment of different δ-opioid agonists is critical because these compounds are being considered as treatments for alcoholism and depression, and giving a high βarr2-recruiting δ-opioid agonist could potentially exacerbate alcoholism rather than attenuate it.

Nicotine.

Very few published studies have examined the influence of βarr2 on nicotine responses. In adolescent mice, nicotine caused hypolocomotion in both wild-type and βarr2-KO animals, and βarr2-KO mice appeared to be more sensitive to this effect (Correll et al., 2009). However, as previously noted, genotype differences in baseline locomotor activity make these results difficult to interpret. βarr2-KO mice also exhibited impaired nicotine-induced locomotor sensitization; whereas repeated nicotine administration significantly increased locomotion in adolescent control mice, adolescent nicotine-induced locomotor activity was stable over time in βarr2-KO mice (Correll et al., 2009). Future experiments are needed to determine whether these βarr2-associated changes in locomotor activity are also reflected in nicotine reward.

As with opioid-dependent individuals, certain polymorphisms of βarr2 have been associated with nicotine users. In European Americans but not African Americans, the rs4790694 SNP of βarr2 significantly correlated with the Heaviness of Smoking Index and the Fagerström Test for Nicotine Dependence (Sun et al., 2008). This finding demonstrated that particular polymorphisms of βarr2 can confer risk of nicotine dependence in certain human populations. Further research is needed to determine the biologic effects of this polymorphism on βarr2 function in neurons. To note, this is not one of the same SNPs that predicted drug relapse while on methadone maintenance therapy (Oneda et al., 2011).

Hallucinogens.

Hallucinogenic effects are mediated by the serotonin (5-HT) system, particularly the 5-HT2A receptor. Studying hallucinations in rodents is difficult due to the cognitive nature of hallucinations; however, rodents treated with hallucinogens exhibit a head twitch that can be quantified, and βarr2 is involved in this behavioral response. Unlike control mice, βarr2-KO mice did not exhibit a head twitch response to moderate doses of the 5-HT precursor 5-HTP; however, βarr2-KOs displayed a normal head twitch to the 5-HT2A receptor agonist 2,5-dimethoxy-4-iodoamphetamine, and had more head twitches than wild-type mice at high doses of 5-HTP (Schmid et al., 2008; Schmid and Bohn, 2010). In addition, 5-HT, but not N-methyltraptamines, engaged a βarr2/phosphoinositide 3-kinase/Src/Akt cascade in cortical neurons (Schmid and Bohn, 2010). Together, these experiments indicate that both N-methyltraptamines and 5-HT induce head twitch via the 5-HT2A receptor, but do so through different mechanisms. βarr2 promotes the 5-HT–induced response but attenuates the N-methyltryptamine–induced response (Schmid and Bohn, 2010). These experiments highlight the importance of functional selectivity of different agonists at the same receptor.

Similar to other hallucinogens, the effects of lysergic acid diethylamide (LSD) are primarily mediated by the serotonin 5-HT2A receptor (De Gregorio et al., 2016), although LSD binds to most serotonin receptors and some other GPCRs (Kroeze et al., 2015). A few studies have used the 5-HT2B receptor, which is very similar to the 5-HT2A receptor, to study the molecular effects of LSD. Compared with 5-HT and other agonists, LSD is strongly biased toward βarr2 signaling over G protein signaling at the 5-HT2B receptor (Wacker et al., 2013), which may contribute to its hallucinogenic effects (Chen and Tesmer, 2017). Recently, the crystal structure of LSD bound to the 5-HT2B receptor was described, and 5-HT2A receptor models show similar binding properties. Interestingly, a portion of an extracellular loop of the receptor (EL2) formed a “lid” over LSD, which prevented LSD from dissociating from the receptor and may be responsible for LSD’s long duration of action. Indeed, mutating part of the lid (L209EL2) resulted in a 10-fold reduction in the duration of time that LSD was bound to the receptor. In addition, this mutation significantly decreased LSD’s recruitment of βarr2 without altering Gq-mediated calcium flux (Wacker et al., 2017). These results indicate that LSD recruits βarr2, and future experiments should examine the behavioral consequences of βarr2 in the hallucinogenic effects of LSD.

A few experiments have examined βarr2’s role in phencyclidine (PCP) effects in the context of schizophrenia, because PCP can induce psychotic-like effects (Urs et al., 2017). PCP robustly increased locomotor activity in wild-type and βarr2-KO mice (Allen et al., 2011). βarr2-biased D2 receptor agonists, such as UNC9994 (5-{3-[4-(2,3-dichlorophenyl)piperidin-1-yl]propoxy}-1,3-benzothiazole) [also known as UNC9994A], have been developed and have antipsychotic-like properties. UNC9994 attenuated PCP-induced locomotion in wild-type mice but had no effect in βarr2-KO mice, demonstrating functional selectivity of the ligand (Allen et al., 2011). Injecting UNC9994A into the mouse prefrontal cortex inhibited PCP-induced locomotion, and eliminating βarr2 in D2-containing neurons prevented this effect. βarr2 in nonstriatal D2 neurons, such as the cortex, likely mediates PCP-induced locomotion because eliminating βarr2 only in D2-containing striatal neurons did not alter the ability of UNC9994A to inhibit PCP-induced locomotion, but virally removing βarr2 in cortical D2 neurons abolished the drug’s effect (Urs et al., 2016). In addition to functional selectivity, UNC9994A caused different effects in D2 receptor-containing neurons in the striatum versus the prefrontal cortex. Whereas UNC9994A did not affect the excitability of striatal MSNs, UNC9994A increased fast-spiking interneuron excitability in the prefrontal cortex, and this effect was mediated by elevated GRK2 expression (Urs et al., 2016). The finding that a biased βarr2 ligand at D2 receptors functions as an agonist in the prefrontal cortex but not in the striatum demonstrates the importance of the brain region–specific properties of βarr2.

Summary

In summary, most rodent experiments examining the contribution of βarr2 to the effects of addictive drugs have used conventional βarr2-KOs. Completely eliminating βarr2 causes changes in the behavioral responses to most classes of drugs of abuse, but whether it blunts, potentiates, or has no effect varies by assay (drug-induced locomotion versus CPP) and drug (Table 1). In the instances where complete loss of βarr2 has no significant reported effects, such as with cocaine, there are a few potential explanations: βarr2 could be uninvolved, βarr1 could be compensating for the lack of βarr2, and/or the assays used lacked sufficient sensitivity to detect a βarr2-KO phenotype. Whole-body deletion of βarr2 typically blunts opioid, psychostimulant, nicotine, and ethanol-induced locomotion; however, loss of βarr2 can potentiate opioid and alcohol reward. Together, these findings indicate that βarr2 is differentially involved in the rewarding versus locomotor-activating effects of drugs and support the notion that locomotor responses to drugs do not always reliably predict their rewarding properties.

The most thorough investigations of βarr2’s involvement in drug effects thus far have been conducted with morphine and amphetamine. βarr2 signaling, particularly in D2-containing MSNs, mediates amphetamine-induced locomotion (Peterson et al., 2015; Urs et al., 2016); however, whether this mechanism also mediates amphetamine reward is currently unknown. By contrast, βarr2 in D1-containing neurons is proposed to mediate morphine-induced locomotion but not reward (Urs et al., 2011; Urs and Caron, 2014). While a simplistic model whereby βarr2 mediates all psychomotor drug effects would be convenient, the data indicate that βarr2 is likely modulating different drug effects in different brain regions through interactions with various GPCRs and intracellular molecules. Much work remains to be done to elucidate how βArr2 modulates the behavioral effects of addictive drugs.

Technical Advances and Limitations

βarr2-KO mice have been a valuable tool for testing the global effects of βarr2. As discussed earlier, however, genetic deletion carries the caveat that adaptations during development may mask, enhance, or otherwise alter βarr2-associated phenotypes. In addition, βarr2-KO mice obscure regional, cell type, and receptor-specific effects. Conditional knockouts whereby βarr2 is eliminated in D1- or D2-contianing cells by crossing floxed βarr2 mice with D1Cre or D2Cre mice (Urs et al., 2016) provide enhanced cell-type specificity but still lack regional specificity because D1 and D2 receptors are expressed in multiple brain regions. The floxed βarr2/A2aCre mice, which lack βarr2 in D2-containing MSNs (Urs et al., 2016), provide enhanced regional and cell-type specificity but do not differentiate between subregions of the striatum, which can have different roles in addictive-like behaviors (Everitt and Robbins, 2013). Depending on the promoter, viral elimination or overexpression of βarr2 can grant further regional and cell type specificity. Experiments using these techniques have focused primarily on knocking out βarr2 (Urs et al., 2016), but using viral vectors to overexpress βarr2 is also possible (Gaval-Cruz et al., 2016).

Viral vectors that express GPCRs with biased βarr2 signaling (Peterson et al., 2015) are a useful tool for dissociating the effects of receptor activation and engagement of multiple signaling pathways with the specific effects of βarr2 in the cells containing that receptor. D2 receptors that preferentially activate βarr2 signaling or traditional Gi/o signaling can be used to dissect the importance of one pathway over the other (Peterson et al., 2015) and are useful for testing the in vivo effects of D2 receptor–mediated activation of each pathway. Developing mutated D1, µ-opioid, and cannabinoid receptors that preferentially induce G protein or βarr2 signaling would also be beneficial for future experiments examining the role of βarr2 in drug effects. The limitation of biased signaling experiments is that they currently require viral infusions that typically result in overexpression of the GPCRs, which may or may not reflect natural βarr2 signaling and function.

Although direct agonists/antagonists of βarr2 are not yet available, biased ligands that are receptor agonists preferentially engaging βarr2 are useful tools for eliciting βarr2 signaling versus canonical G protein signaling. For example, there are D2 receptor ligands that function as partial agonists engaging βarr2 but not G protein signaling (Allen et al., 2011), and there are κ-opioid receptor agonists that harness G protein but not βarr signaling (Rives et al., 2012). Additional drugs that specifically and acutely target βArr2 would be beneficial to more thoroughly investigate the role of this protein in modulating behavioral responses to drugs of abuse.

Designer receptors exclusively activated by designer drugs (DREADDs), which use mutated receptors with selective ligands to activate or inactivate particular cells or signaling pathways, have become a popular tool in neuroscience research recently (Roth, 2016; Smith et al., 2016). A DREADD has been invented that activates βarrs but not G proteins (Nakajima et al., 2015), which could be very useful for preferentially activating βarrs without causing signaling from endogenous receptors. To our knowledge, this βarr DREADD has not yet been employed to investigate βarr2 contributions to behavior or in relation to drugs of abuse.

Another limitation in studying βarr2 is the difficulty in visualizing the protein. Immunohistochemistry and western blot experiments have suffered from a lack of commercially available, sensitive, and specific βarr2 antibodies. Some investigator-produced antibodies have yielded better results (Urs et al., 2016), but these resources are limited. Recently, βarr2 biosensors have been developed to detect in vitro real-time conformational changes in βarr2 and the “megaplexes” that can form combining internalized GPCR, βarr2, and G protein (Nuber et al., 2016). These sensors could be useful in visualizing the precise conformational changes and intracellular movements of βarr2 in response to drugs of abuse.

Surprisingly, only a few experiments to date have used electrophysiology to examine how βarr2 manipulations affect the excitability of neurons within reward circuits. Enkephalin hyperpolarized locus coeruleus neurons to the same degree in βarr2-KO and control neurons (Arttamangkul et al., 2008). Interestingly, the βarr2-biased D2 ligand UNC9994A had little effect on striatal MSNs but increased the excitability of fast-spiking interneurons in the prefrontal cortex. This increased activity in the cortex was attenuated in βarr2-KOs, indicating that βarr2 mediates the effects of UNC9994A on cell excitability (Urs et al., 2016). In addition, whereas the D2 agonist quinpirole normally decreases the excitability of MSNs, it increased the excitability of MSNs in Dbh −/− mice that have decreased βarr2 in the nucleus accumbens (Gaval-Cruz et al., 2016). These experiments hint at the complex effects that βarr2 can have on neural activity in different brain regions. Future experiments should investigate psychostimulant- and opioid-induced changes in the excitability of D1- and D2-containing MSNs and prefrontal cortical neurons after βarr2 manipulations. Additionally, βarr2’s role in synaptic plasticity after drug use should be examined.

Because the defining symptoms of drug abuse are behavioral, biologic targets for treating drug abuse must be able to change either the reinforcing properties of drugs or the motivation to take drugs. Most experiments examining the behavioral effects of βarr2 manipulations have used simple behavioral procedures, such as drug-induced locomotion, locomotor sensitization, or CPP. These behavioral tasks are useful screens for measuring drug responses because they are reliable, technically simple, inexpensive, and quantitative; however, on their own, they are inadequate assays for addiction. Future studies should use operant drug self-administration procedures that can answer more sophisticated behavioral questions probing voluntary intake, escalation of intake, drug consumption despite adverse consequences, and relapse-like behavior.

Acknowledgments

The authors thank C. Strauss for helpful editing of the manuscript.

Authorship Contributions

Wrote or contributed to the writing of the manuscript: Porter-Stransky, Weinshenker.

Footnotes

    • Received February 7, 2017.
    • Accepted March 15, 2017.
  • This research was supported by the National Institutes of Health National Institute on Drug Abuse [R01 DA038453 (to D.W.)] and the National Institutes of Health National Institute of Neurological Disorders and Stroke [F32 NS098615 (to K.A.P.-S.)].

  • https://doi.org/10.1124/jpet.117.240622.

Abbreviations

5-HT
serotonin
βarr
β-arrestin
CP55940
(−)-cis-3-[2-hydroxy-4-(1,1-dimethylheptyl)phenyl]-trans-4-(3-hydroxypropyl)cyclohexanol
CPP
conditioned place preference
DAMGO
(2S)-2-[[2-[[(2R)-2-[[(2S)-2-amino-3-(4-hydroxyphenyl)propanoyl]amino]propanoyl]amino]acetyl]-methylamino]-N-(2-hydroxyethyl)-3-phenylpropanamide
DREADD
designer receptors exclusively activated by designer drugs
ERK
extracellular signal–regulated kinase
GPCR
G protein–coupled receptor
JNK
c-Jun N-terminal-activated protein kinase kinase
JWH-073
(1-butyl-1H-indol-3-yl)-1-naphthalenyl-methanone
KO
knockout
LSD
lysergic acid diethylamide
MEK
mitogen-activated protein kinase kinase
MSN
medium spiny neuron
O-1812
(5Z,8Z,11Z,14Z)-20-cyano-N-[(2R)-1-hydroxypropan-2-yl]-16,16-dimethylicosa-5,8,11,14-tetraenamide
PCP
phencyclidine
PZM21
1-[(2S)-2-(dimethylamino)-3-(4-hydroxyphenyl)propyl]-3-[(2S)-1-(thiophen-3-yl)propan-2-yl]urea
SNP
single nucleotide polymorphism
UNC9994 (5-{3-[4-(2
3-dichlorophenyl)piperidin-1-yl]propoxy}-1,3-benzothiazole
  • Copyright © 2017 by The American Society for Pharmacology and Experimental Therapeutics

References

  1. ↵
    1. Ahn S,
    2. Wei H,
    3. Garrison TR, and
    4. Lefkowitz RJ
    (2004) Reciprocal regulation of angiotensin receptor-activated extracellular signal-regulated kinases by beta-arrestins 1 and 2. J Biol Chem 279:7807–7811.
    OpenUrlAbstract/FREE Full Text
  2. ↵
    1. Allen JA,
    2. Yost JM,
    3. Setola V,
    4. Chen X,
    5. Sassano MF,
    6. Chen M,
    7. Peterson S,
    8. Yadav PN,
    9. Huang XP,
    10. Feng B, et al.
    (2011) Discovery of β-arrestin-biased dopamine D2 ligands for probing signal transduction pathways essential for antipsychotic efficacy. Proc Natl Acad Sci USA 108:18488–18493.
    OpenUrlAbstract/FREE Full Text
  3. ↵
    1. Arttamangkul S,
    2. Quillinan N,
    3. Low MJ,
    4. von Zastrow M,
    5. Pintar J, and
    6. Williams JT
    (2008) Differential activation and trafficking of micro-opioid receptors in brain slices. Mol Pharmacol 74:972–979.
    OpenUrlAbstract/FREE Full Text
  4. ↵
    1. Attramadal H,
    2. Arriza JL,
    3. Aoki C,
    4. Dawson TM,
    5. Codina J,
    6. Kwatra MM,
    7. Snyder SH,
    8. Caron MG, and
    9. Lefkowitz RJ
    (1992) Beta-arrestin2, a novel member of the arrestin/beta-arrestin gene family. J Biol Chem 267:17882–17890.
    OpenUrlAbstract/FREE Full Text
  5. ↵
    1. Atwood BK,
    2. Wager-Miller J,
    3. Haskins C,
    4. Straiker A, and
    5. Mackie K
    (2012) Functional selectivity in CB(2) cannabinoid receptor signaling and regulation: implications for the therapeutic potential of CB(2) ligands. Mol Pharmacol 81:250–263.
    OpenUrlAbstract/FREE Full Text
  6. ↵
    1. Beaulieu JM and
    2. Gainetdinov RR
    (2011) The physiology, signaling, and pharmacology of dopamine receptors. Pharmacol Rev 63:182–217.
    OpenUrlAbstract/FREE Full Text
  7. ↵
    1. Beaulieu JM,
    2. Sotnikova TD,
    3. Marion S,
    4. Lefkowitz RJ,
    5. Gainetdinov RR, and
    6. Caron MG
    (2005) An Akt/beta-arrestin 2/PP2A signaling complex mediates dopaminergic neurotransmission and behavior. Cell 122:261–273.
    OpenUrlCrossRefPubMed
  8. ↵
    1. Berger AC and
    2. Whistler JL
    (2011) Morphine-induced mu opioid receptor trafficking enhances reward yet prevents compulsive drug use. EMBO Mol Med 3:385–397.
    OpenUrlAbstract/FREE Full Text
  9. ↵
    1. Björk K,
    2. Rimondini R,
    3. Hansson AC,
    4. Terasmaa A,
    5. Hyytiä P,
    6. Heilig M, and
    7. Sommer WH
    (2008) Modulation of voluntary ethanol consumption by beta-arrestin 2. FASEB J 22:2552–2560.
    OpenUrlAbstract/FREE Full Text
  10. ↵
    1. Björk K,
    2. Tronci V,
    3. Thorsell A,
    4. Tanda G,
    5. Hirth N,
    6. Heilig M,
    7. Hansson AC, and
    8. Sommer WH
    (2013) β-arrestin 2 knockout mice exhibit sensitized dopamine release and increased reward in response to a low dose of alcohol. Psychopharmacology (Berl) 230:439–449.
    OpenUrl
  11. ↵
    1. Boerrigter G,
    2. Soergel DG,
    3. Violin JD,
    4. Lark MW, and
    5. Burnett JC Jr.
    (2012) TRV120027, a novel β-arrestin biased ligand at the angiotensin II type I receptor, unloads the heart and maintains renal function when added to furosemide in experimental heart failure. Circ Heart Fail 5:627–634.
    OpenUrlAbstract/FREE Full Text
  12. ↵
    1. Bohn LM,
    2. Dykstra LA,
    3. Lefkowitz RJ,
    4. Caron MG, and
    5. Barak LS
    (2004a) Relative opioid efficacy is determined by the complements of the G protein-coupled receptor desensitization machinery. Mol Pharmacol 66:106–112.
    OpenUrlAbstract/FREE Full Text
  13. ↵
    1. Bohn LM,
    2. Gainetdinov RR, and
    3. Caron MG
    (2004b) G protein-coupled receptor kinase/β-arrestin systems and drugs of abuse: psychostimulant and opiate studies in knockout mice. Neuromolecular Med 5:41–50.
    OpenUrlCrossRefPubMed
  14. ↵
    1. Bohn LM,
    2. Gainetdinov RR,
    3. Sotnikova TD,
    4. Medvedev IO,
    5. Lefkowitz RJ,
    6. Dykstra LA, and
    7. Caron MG
    (2003) Enhanced rewarding properties of morphine, but not cocaine, in β(arrestin)-2 knock-out mice. J Neurosci 23:10265–10273.
    OpenUrlAbstract/FREE Full Text
  15. ↵
    1. Bohn LM,
    2. Lefkowitz RJ, and
    3. Caron MG
    (2002) Differential mechanisms of morphine antinociceptive tolerance revealed in (beta)arrestin-2 knock-out mice. J Neurosci 22:10494–10500.
    OpenUrlAbstract/FREE Full Text
  16. ↵
    1. Bohn LM,
    2. Lefkowitz RJ,
    3. Gainetdinov RR,
    4. Peppel K,
    5. Caron MG, and
    6. Lin FT
    (1999) Enhanced morphine analgesia in mice lacking beta-arrestin 2. Science 286:2495–2498.
    OpenUrlAbstract/FREE Full Text
  17. ↵
    1. Breivogel CS,
    2. Lambert JM,
    3. Gerfin S,
    4. Huffman JW, and
    5. Razdan RK
    (2008) Sensitivity to delta9-tetrahydrocannabinol is selectively enhanced in beta-arrestin2 -/- mice. Behav Pharmacol 19:298–307.
    OpenUrlCrossRefPubMed
  18. ↵
    1. Chen Q and
    2. Tesmer JJ
    (2017) A receptor on acid. Cell 168:339–341.
    OpenUrl
  19. ↵
    1. Chiang T,
    2. Sansuk K, and
    3. van Rijn RM
    (2016) β-arrestin 2 dependence of δ opioid receptor agonists is correlated with alcohol intake. Br J Pharmacol 173:332–343.
    OpenUrl
  20. ↵
    1. Correll JA,
    2. Noel DM,
    3. Sheppard AB,
    4. Thompson KN,
    5. Li Y,
    6. Yin D, and
    7. Brown RW
    (2009) Nicotine sensitization and analysis of brain-derived neurotrophic factor in adolescent beta-arrestin-2 knockout mice. Synapse 63:510–519.
    OpenUrlPubMed
  21. ↵
    1. Daigle TL,
    2. Kearn CS, and
    3. Mackie K
    (2008) Rapid CB1 cannabinoid receptor desensitization defines the time course of ERK1/2 MAP kinase signaling. Neuropharmacology 54:36–44.
    OpenUrlCrossRefPubMed
  22. ↵
    1. De Gregorio D,
    2. Comai S,
    3. Posa L, and
    4. Gobbi G
    (2016) d-Lysergic acid diethylamide (LSD) as a model of psychosis: mechanism of action and pharmacology. Int J Mol Sci 17:1953.
    OpenUrl
  23. ↵
    1. Del’guidice T,
    2. Lemasson M, and
    3. Beaulieu JM
    (2011) Role of beta-arrestin 2 downstream of dopamine receptors in the basal ganglia. Front Neuroanat 5:58.
    OpenUrlPubMed
  24. ↵
    1. Delgado-Peraza F,
    2. Ahn KH,
    3. Nogueras-Ortiz C,
    4. Mungrue IN,
    5. Mackie K,
    6. Kendall DA, and
    7. Yudowski GA
    (2016) Mechanisms of biased β-arrestin-mediated signaling downstream from the cannabinoid 1 receptor. Mol Pharmacol 89:618–629.
    OpenUrlAbstract/FREE Full Text
  25. ↵
    1. Di Chiara G and
    2. Imperato A
    (1988) Drugs abused by humans preferentially increase synaptic dopamine concentrations in the mesolimbic system of freely moving rats. Proc Natl Acad Sci USA 85:5274–5278.
    OpenUrlAbstract/FREE Full Text
  26. ↵
    1. Dolph PJ
    (2002) Arrestin: roles in the life and death of retinal neurons. Neuroscientist 8:347–355.
    OpenUrlCrossRefPubMed
  27. ↵
    1. Everitt BJ and
    2. Robbins TW
    (2013) From the ventral to the dorsal striatum: devolving views of their roles in drug addiction. Neurosci Biobehav Rev 37:1946–1954.
    OpenUrlCrossRefPubMed
  28. ↵
    1. Fan XL,
    2. Zhang JS,
    3. Zhang XQ,
    4. Yue W, and
    5. Ma L
    (2003) Differential regulation of β-arrestin 1 and β-arrestin 2 gene expression in rat brain by morphine. Neuroscience 117:383–389.
    OpenUrlCrossRefPubMed
  29. ↵
    1. Ferrer-Alcón M,
    2. La Harpe R, and
    3. García-Sevilla JA
    (2004) Decreased immunodensities of micro-opioid receptors, receptor kinases GRK 2/6 and beta-arrestin-2 in postmortem brains of opiate addicts. Brain Res Mol Brain Res 121:114–122.
    OpenUrlCrossRefPubMed
  30. ↵
    1. Finn AK and
    2. Whistler JL
    (2001) Endocytosis of the mu opioid receptor reduces tolerance and a cellular hallmark of opiate withdrawal. Neuron 32:829–839.
    OpenUrlCrossRefPubMed
  31. ↵
    1. Franklin JM,
    2. Vasiljevik T,
    3. Prisinzano TE, and
    4. Carrasco GA
    (2013) Cannabinoid agonists increase the interaction between β-arrestin 2 and ERK1/2 and upregulate β-arrestin 2 and 5-HT(2A) receptors. Pharmacol Res 68:46–58.
    OpenUrlCrossRefPubMed
  32. ↵
    1. Gao H,
    2. Sun Y,
    3. Wu Y,
    4. Luan B,
    5. Wang Y,
    6. Qu B, and
    7. Pei G
    (2004) Identification of β-arrestin2 as a G protein-coupled receptor-stimulated regulator of NF-kappaB pathways. Mol Cell 14:303–317.
    OpenUrlCrossRefPubMed
  33. ↵
    1. Gaval-Cruz M,
    2. Goertz RB,
    3. Puttick DJ,
    4. Bowles DE,
    5. Meyer RC,
    6. Hall RA,
    7. Ko D,
    8. Paladini CA, and
    9. Weinshenker D
    (2016) Chronic loss of noradrenergic tone produces β-arrestin2-mediated cocaine hypersensitivity and alters cellular D2 responses in the nucleus accumbens. Addict Biol 21:35–48.
    OpenUrl
  34. ↵
    1. Groer CE,
    2. Schmid CL,
    3. Jaeger AM, and
    4. Bohn LM
    (2011) Agonist-directed interactions with specific β-arrestins determine μ-opioid receptor trafficking, ubiquitination, and dephosphorylation. J Biol Chem 286:31731–31741.
    OpenUrlAbstract/FREE Full Text
  35. ↵
    1. Gurevich VV and
    2. Gurevich EV
    (2004) The molecular acrobatics of arrestin activation. Trends Pharmacol Sci 25:105–111.
    OpenUrlCrossRefPubMed
  36. ↵
    1. Haberstock-Debic H,
    2. Kim KA,
    3. Yu YJ, and
    4. von Zastrow M
    (2005) Morphine promotes rapid, arrestin-dependent endocytosis of μ-opioid receptors in striatal neurons. J Neurosci 25:7847–7857.
    OpenUrlAbstract/FREE Full Text
  37. ↵
    1. Irannejad R,
    2. Tomshine JC,
    3. Tomshine JR,
    4. Chevalier M,
    5. Mahoney JP,
    6. Steyaert J,
    7. Rasmussen SG,
    8. Sunahara RK,
    9. El-Samad H,
    10. Huang B, et al.
    (2013) Conformational biosensors reveal GPCR signalling from endosomes. Nature 495:534–538.
    OpenUrlCrossRefPubMed
  38. ↵
    1. Keith DE,
    2. Anton B,
    3. Murray SR,
    4. Zaki PA,
    5. Chu PC,
    6. Lissin DV,
    7. Monteillet-Agius G,
    8. Stewart PL,
    9. Evans CJ, and
    10. von Zastrow M
    (1998) mu-Opioid receptor internalization: opiate drugs have differential effects on a conserved endocytic mechanism in vitro and in the mammalian brain. Mol Pharmacol 53:377–384.
    OpenUrlAbstract/FREE Full Text
  39. ↵
    1. Kravitz AV,
    2. Tye LD, and
    3. Kreitzer AC
    (2012) Distinct roles for direct and indirect pathway striatal neurons in reinforcement. Nat Neurosci 15:816–818.
    OpenUrlCrossRefPubMed
  40. ↵
    1. Kroeze WK,
    2. Sassano MF,
    3. Huang X-P,
    4. Lansu K,
    5. McCorvy JD,
    6. Giguère PM,
    7. Sciaky N, and
    8. Roth BL
    (2015) PRESTO-Tango as an open-source resource for interrogation of the druggable human GPCRome. Nat Struct Mol Biol 22:362–369.
    OpenUrlCrossRefPubMed
  41. ↵
    1. Kuhar JR,
    2. Bedini A,
    3. Melief EJ,
    4. Chiu YC,
    5. Striegel HN, and
    6. Chavkin C
    (2015) Mu opioid receptor stimulation activates c-Jun N-terminal kinase 2 by distinct arrestin-dependent and independent mechanisms. Cell Signal 27:1799–1806.
    OpenUrl
  42. ↵
    1. Lee HJ,
    2. Weitz AJ,
    3. Bernal-Casas D,
    4. Duffy BA,
    5. Choy M,
    6. Kravitz AV,
    7. Kreitzer AC, and
    8. Lee JH
    (2016) Activation of direct and indirect pathway medium spiny neurons drives distinct brain-wide responses. Neuron 91:412–424.
    OpenUrl
  43. ↵
    1. Li H,
    2. Tao Y,
    3. Ma L,
    4. Liu X, and
    5. Ma L
    (2013) β-arrestin-2 inhibits preference for alcohol in mice and suppresses Akt signaling in the dorsal striatum. Neurosci Bull 29:531–540.
    OpenUrl
  44. ↵
    1. Lobo MK and
    2. Nestler EJ
    (2011) The striatal balancing act in drug addiction: distinct roles of direct and indirect pathway medium spiny neurons. Front Neuroanat 5:41.
    OpenUrlCrossRefPubMed
  45. ↵
    1. Lüscher C and
    2. Ungless MA
    (2006) The mechanistic classification of addictive drugs. PLoS Med 3:e437.
    OpenUrlCrossRefPubMed
  46. ↵
    1. Luttrell LM,
    2. Maudsley S, and
    3. Bohn LM
    (2015) Fulfilling the promise of “biased” G protein-coupled receptor agonism. Mol Pharmacol 88:579–588.
    OpenUrlAbstract/FREE Full Text
  47. ↵
    1. Luttrell LM,
    2. Roudabush FL,
    3. Choy EW,
    4. Miller WE,
    5. Field ME,
    6. Pierce KL, and
    7. Lefkowitz RJ
    (2001) Activation and targeting of extracellular signal-regulated kinases by β-arrestin scaffolds. Proc Natl Acad Sci USA 98:2449–2454.
    OpenUrlAbstract/FREE Full Text
  48. ↵
    1. Mahavadi S,
    2. Sriwai W,
    3. Huang J,
    4. Grider JR, and
    5. Murthy KS
    (2014) Inhibitory signaling by CB1 receptors in smooth muscle mediated by GRK5/β-arrestin activation of ERK1/2 and Src kinase. Am J Physiol Gastrointest Liver Physiol 306:G535–G545.
    OpenUrlAbstract/FREE Full Text
  49. ↵
    1. Manglik A,
    2. Lin H,
    3. Aryal DK,
    4. McCorvy JD,
    5. Dengler D,
    6. Corder G,
    7. Levit A,
    8. Kling RC,
    9. Bernat V,
    10. Hübner H, et al.
    (2016) Structure-based discovery of opioid analgesics with reduced side effects. Nature 537:185–190.
    OpenUrlCrossRefPubMed
  50. ↵
    1. McGuinness D,
    2. Malikzay A,
    3. Visconti R,
    4. Lin K,
    5. Bayne M,
    6. Monsma F, and
    7. Lunn CA
    (2009) Characterizing cannabinoid CB2 receptor ligands using DiscoveRx PathHunter beta-arrestin assay. J Biomol Screen 14:49–58.
    OpenUrlCrossRefPubMed
  51. ↵
    Nakajima K, Gimenez LED, Gurevich VV, and Wess J (2015) Design and analysis of an arrestin-biased DREADD. Designer Receptors Exclusively Activated by Designer Drugs (Thiel G ed) vol 108, pp 29–48, Springer, New York.
  52. ↵
    1. Nguyen PT,
    2. Schmid CL,
    3. Raehal KM,
    4. Selley DE,
    5. Bohn LM, and
    6. Sim-Selley LJ
    (2012) β-arrestin2 regulates cannabinoid CB1 receptor signaling and adaptation in a central nervous system region-dependent manner. Biol Psychiatry 71:714–724.
    OpenUrlCrossRefPubMed
  53. ↵
    1. Nuber S,
    2. Zabel U,
    3. Lorenz K,
    4. Nuber A,
    5. Milligan G,
    6. Tobin AB,
    7. Lohse MJ, and
    8. Hoffmann C
    (2016) β-arrestin biosensors reveal a rapid, receptor-dependent activation/deactivation cycle. Nature 531:661–664.
    OpenUrlCrossRefPubMed
  54. ↵
    1. Oakley RH,
    2. Laporte SA,
    3. Holt JA,
    4. Caron MG, and
    5. Barak LS
    (2000) Differential affinities of visual arrestin, β arrestin1, and β arrestin2 for G protein-coupled receptors delineate two major classes of receptors. J Biol Chem 275:17201–17210.
    OpenUrlAbstract/FREE Full Text
  55. ↵
    1. Oneda B,
    2. Crettol S,
    3. Bochud M,
    4. Besson J,
    5. Croquette-Krokar M,
    6. Hämmig R,
    7. Monnat M,
    8. Preisig M, and
    9. Eap CB
    (2011) β-arrestin2 influences the response to methadone in opioid-dependent patients. Pharmacogenomics J 11:258–266.
    OpenUrlPubMed
  56. ↵
    1. Oneda B,
    2. Preisig M,
    3. Dobrinas M, and
    4. Eap CB
    (2010) Lack of association between genetic polymorphisms of ARRB2 and alcohol dependence in a Caucasian population. Alcohol Alcohol 45:590–591.
    OpenUrlFREE Full Text
  57. ↵
    1. Peterson SM,
    2. Pack TF,
    3. Wilkins AD,
    4. Urs NM,
    5. Urban DJ,
    6. Bass CE,
    7. Lichtarge O, and
    8. Caron MG
    (2015) Elucidation of G-protein and β-arrestin functional selectivity at the dopamine D2 receptor. Proc Natl Acad Sci USA 112:7097–7102.
    OpenUrlAbstract/FREE Full Text
  58. ↵
    1. Pierce RC and
    2. Kumaresan V
    (2006) The mesolimbic dopamine system: the final common pathway for the reinforcing effect of drugs of abuse? Neurosci Biobehav Rev 30:215–238.
    OpenUrlCrossRefPubMed
  59. ↵
    1. Raehal KM and
    2. Bohn LM
    (2011) The role of beta-arrestin2 in the severity of antinociceptive tolerance and physical dependence induced by different opioid pain therapeutics. Neuropharmacology 60:58–65.
    OpenUrlCrossRefPubMed
  60. ↵
    Raehal KM and Bohn LM (2014) β-arrestins: regulatory role and therapeutic potential in opioid and cannabinoid receptor-mediated analgesia. Handb Exp Pharmacol 219:427–443.
  61. ↵
    1. Raehal KM,
    2. Walker JKL, and
    3. Bohn LM
    (2005) Morphine side effects in beta-arrestin 2 knockout mice. J Pharmacol Exp Ther 314:1195–1201.
    OpenUrlAbstract/FREE Full Text
  62. ↵
    1. Rives ML,
    2. Rossillo M,
    3. Liu-Chen L-Y, and
    4. Javitch JA
    (2012) 6′-Guanidinonaltrindole (6′-GNTI) is a G protein-biased κ-opioid receptor agonist that inhibits arrestin recruitment. J Biol Chem 287:27050–27054.
    OpenUrlAbstract/FREE Full Text
  63. ↵
    1. Roth BL
    (2016) DREADDs for neuroscientists. Neuron 89:683–694.
    OpenUrlCrossRefPubMed
  64. ↵
    1. Schmid CL and
    2. Bohn LM
    (2010) Serotonin, but not N-methyltryptamines, activates the serotonin 2A receptor via a ß-arrestin2/Src/Akt signaling complex in vivo. J Neurosci 30:13513–13524.
    OpenUrlAbstract/FREE Full Text
  65. ↵
    1. Schmid CL,
    2. Raehal KM, and
    3. Bohn LM
    (2008) Agonist-directed signaling of the serotonin 2A receptor depends on beta-arrestin-2 interactions in vivo. Proc Natl Acad Sci USA 105:1079–1084.
    OpenUrlAbstract/FREE Full Text
  66. ↵
    1. Schmitt KC and
    2. Reith ME
    (2010) Regulation of the dopamine transporter: aspects relevant to psychostimulant drugs of abuse. Ann N Y Acad Sci 1187:316–340.
    OpenUrlCrossRefPubMed
  67. ↵
    1. Shenoy SK,
    2. Drake MT,
    3. Nelson CD,
    4. Houtz DA,
    5. Xiao K,
    6. Madabushi S,
    7. Reiter E,
    8. Premont RT,
    9. Lichtarge O, and
    10. Lefkowitz RJ
    (2006) Beta-arrestin-dependent, G protein-independent ERK1/2 activation by the beta2 adrenergic receptor. J Biol Chem 281:1261–1273.
    OpenUrlAbstract/FREE Full Text
  68. ↵
    1. Shenoy SK,
    2. McDonald PH,
    3. Kohout TA, and
    4. Lefkowitz RJ
    (2001) Regulation of receptor fate by ubiquitination of activated β 2-adrenergic receptor and β-arrestin. Science 294:1307–1313.
    OpenUrlAbstract/FREE Full Text
  69. ↵
    1. Smith JS and
    2. Rajagopal S
    (2016) The β-arrestins: multifunctional regulators of G protein-coupled receptors. J Biol Chem 291:8969–8977.
    OpenUrlAbstract/FREE Full Text
  70. ↵
    1. Smith KS,
    2. Bucci DJ,
    3. Luikart BW, and
    4. Mahler SV
    (2016) DREADDS: use and application in behavioral neuroscience. Behav Neurosci 130:137–155.
    OpenUrlCrossRefPubMed
  71. ↵
    1. Soergel DG,
    2. Subach RA,
    3. Burnham N,
    4. Lark MW,
    5. James IE,
    6. Sadler BM,
    7. Skobieranda F,
    8. Violin JD, and
    9. Webster LR
    (2014) Biased agonism of the μ-opioid receptor by TRV130 increases analgesia and reduces on-target adverse effects versus morphine: A randomized, double-blind, placebo-controlled, crossover study in healthy volunteers. Pain 155:1829–1835.
    OpenUrlCrossRefPubMed
  72. ↵
    1. Sun D,
    2. Ma JZ,
    3. Payne TJ, and
    4. Li MD
    (2008) Beta-arrestins 1 and 2 are associated with nicotine dependence in European American smokers. Mol Psychiatry 13:398–406.
    OpenUrlCrossRefPubMed
  73. ↵
    1. Tarigopula M,
    2. Davis RT 3rd.,
    3. Mungai PT,
    4. Ryba DM,
    5. Wieczorek DF,
    6. Cowan CL,
    7. Violin JD,
    8. Wolska BM, and
    9. Solaro RJ
    (2015) Cardiac myosin light chain phosphorylation and inotropic effects of a biased ligand, TRV120023, in a dilated cardiomyopathy model. Cardiovasc Res 107:226–234.
    OpenUrlAbstract/FREE Full Text
  74. ↵
    1. Turu G and
    2. Hunyady L
    (2010) Signal transduction of the CB1 cannabinoid receptor. J Mol Endocrinol 44:75–85.
    OpenUrlAbstract/FREE Full Text
  75. ↵
    1. Urs NM and
    2. Caron MG
    (2014) The physiological relevance of functional selectivity in dopamine signalling. Int J Obes Suppl 4 (Suppl 1):S5–S8.
    OpenUrl
  76. ↵
    1. Urs NM,
    2. Daigle TL, and
    3. Caron MG
    (2011) A dopamine D1 receptor-dependent β-arrestin signaling complex potentially regulates morphine-induced psychomotor activation but not reward in mice. Neuropsychopharmacology 36:551–558.
    OpenUrlCrossRefPubMed
  77. ↵
    1. Urs NM,
    2. Gee SM,
    3. Pack TF,
    4. McCorvy JD,
    5. Evron T,
    6. Snyder JC,
    7. Yang X,
    8. Rodriguiz RM,
    9. Borrelli E,
    10. Wetsel WC, et al.
    (2016) Distinct cortical and striatal actions of a β-arrestin-biased dopamine D2 receptor ligand reveal unique antipsychotic-like properties. Proc Natl Acad Sci USA 113:E8178–E8186.
    OpenUrlAbstract/FREE Full Text
  78. ↵
    1. Urs NM,
    2. Peterson SM, and
    3. Caron MG
    (2017) New concepts in dopamine D2 receptor biased signaling and implications for schizophrenia therapy. Biol Psychiatry 81:78–85.
    OpenUrl
  79. ↵
    1. van der Lee MMC,
    2. Blomenröhr M,
    3. van der Doelen AA,
    4. Wat JWY,
    5. Smits N,
    6. Hanson BJ,
    7. van Koppen CJ, and
    8. Zaman GJR
    (2009) Pharmacological characterization of receptor redistribution and beta-arrestin recruitment assays for the cannabinoid receptor 1. J Biomol Screen 14:811–823.
    OpenUrlCrossRefPubMed
  80. ↵
    1. Wacker D,
    2. Wang C,
    3. Katritch V,
    4. Han GW,
    5. Huang XP,
    6. Vardy E,
    7. McCorvy JD,
    8. Jiang Y,
    9. Chu M,
    10. Siu FY, et al.
    (2013) Structural features for functional selectivity at serotonin receptors. Science 340:615–619.
    OpenUrlAbstract/FREE Full Text
  81. ↵
    Wacker D, Wang S, McCorvy JD, Betz RM, Venkatakrishnan A, Levit A, Lansu K, Schools ZL, Che T, and Nichols DE (2017) Crystal structure of an LSD-bound human serotonin receptor. Cell 168:377–389.
  82. ↵
    1. Wehbi VL,
    2. Stevenson HP,
    3. Feinstein TN,
    4. Calero G,
    5. Romero G, and
    6. Vilardaga J-P
    (2013) Noncanonical GPCR signaling arising from a PTH receptor-arrestin-Gβγ complex. Proc Natl Acad Sci USA 110:1530–1535.
    OpenUrlAbstract/FREE Full Text
  83. ↵
    1. Whistler JL and
    2. von Zastrow M
    (1998) Morphine-activated opioid receptors elude desensitization by beta-arrestin. Proc Natl Acad Sci USA 95:9914–9919.
    OpenUrlAbstract/FREE Full Text
  84. ↵
    1. Zhang J,
    2. Ferguson SSG,
    3. Barak LS,
    4. Bodduluri SR,
    5. Laporte SA,
    6. Law PY, and
    7. Caron MG
    (1998) Role for G protein-coupled receptor kinase in agonist-specific regulation of mu-opioid receptor responsiveness. Proc Natl Acad Sci USA 95:7157–7162.
    OpenUrlAbstract/FREE Full Text
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Journal of Pharmacology and Experimental Therapeutics: 361 (3)
Journal of Pharmacology and Experimental Therapeutics
Vol. 361, Issue 3
1 Jun 2017
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β-Arrestin 2 and Drug Addiction

Kirsten A. Porter-Stransky and David Weinshenker
Journal of Pharmacology and Experimental Therapeutics June 1, 2017, 361 (3) 341-348; DOI: https://doi.org/10.1124/jpet.117.240622

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β-Arrestin 2 and Drug Addiction

Kirsten A. Porter-Stransky and David Weinshenker
Journal of Pharmacology and Experimental Therapeutics June 1, 2017, 361 (3) 341-348; DOI: https://doi.org/10.1124/jpet.117.240622
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