Advances in the neurobiological bases for food ‘liking’ versus ‘wanting’
Introduction
Over the last 15 years, research has yielded several unexpected findings on how hedonic circuitry in the brain interacts with food to produce reward and appetite. Evidence now suggests that discrete, anatomically localized “hedonic hotspots” exist in limbic-related brain structures, and are able to magnify the hedonic impact of natural sensory rewards, such as sweet tastes. So far, these hotspots have been found in the forebrain nucleus accumbens (particularly in medial shell), ventral pallidum, and in the brainstem parabrachial nucleus. In this review, we will discuss where these hotspots were found, what neurochemical systems enhance hedonic impact in them, and how the hotspots may interact within hedonic circuitry and with a larger mesocorticolimbic circuitry that produces appetite or the motivation to eat.
The nucleus accumbens (NAc), as well as the striatum as a whole, is well known to be involved in reward and motivation. However, it has also become increasingly clear that subregions within the nucleus accumbens and striatum can differently influence distinct aspects of behavior and motivation [6], [39], [84], [134]. One potential contributing factor may be related to the anatomical make up of different zones within the striatum. For example, though there are general striatal neurobiological features shared by NAc and neostriatum (D1/Dynorphin and D2/Enkephalin descending projections, inputs from prefrontal cortex, amygdala, and hippocampal nuclei, etc.), there are also clear anatomical differences between ventral and dorsal striatum, between core and shell components within nucleus accumbens, and even between different subregions within the medial shell of the nucleus accumbens [52], [61], [73], [117], [133].
The taste reactivity test can be used as an objective measure of hedonic impact or ‘liking’ reactions to taste palatability, based on quantifying discrete orofacial affective reactions to different tastes [112]. Originally applied to rats in behavioral neuroscience studies by Grill and Norgren for use in decerebrate and thalamic rats [48], [49], this affective reactivity test was even earlier pioneered in human infants [111]. Converging evidence from animal and human comparisons showed that the orofacial reactions elicited by rats and humans (as well as several species of apes, monkeys, horses and mice), in response to palatable or unpalatable tastes, are strikingly homologous, with positive hedonic ‘liking’ reactions including tongue protrusions, lateral tongue protrusions and paw licks, and negative ‘disgust’ reactions including gapes, head shakes, and chin rubs [62], [112]. ‘Liking’ and ‘disgust’ are placed in quotation marks to acknowledge that these are objective positive or negative hedonic reactions that are not necessarily accompanied by subjective feelings of pleasure or disgust (even if they often are) [94], [125], and to distinguish them from the everyday use of the English term, liking. Similarly, ‘wanting’ in quotes refers specifically to the motivation process of incentive salience, which also can occur in brain and behavioral responses either with or without accompanying subjective feelings of ordinary wanting [94], [125].
While at first it seemed possible that these taste-elicited reactions were merely sensory-specific reactions (e.g. sweet versus bitter), or merely brainstem reflexes rather than affective responses (taste reactions are emitted by decerebrates with only a brainstem to control behavior [47], [49]), accumulating studies suggested that the orofacial reactions truly reflected hedonic impact for intact-brain individuals by the 1980s. For example, initially ‘liked’ tastes, such as sugars or saccharin, after being paired with injections of lithium chloride to produce a conditioned taste aversion (CTA), subsequently produced aversive gapes, which requires forebrain control [12], [49], [82], [109], [123]. Reciprocally, intraoral infusions of a normally disgusting hypertonic NaCl solution (e.g., 1.5 M) can produce hedonic reactions in a salt depleted state [19], [33], [93], [118]. Further, affective orofacial reaction patterns are not tied to particular sensory stimuli in any one-to-one fashion that would reflect sensory-specific coding; palatable sucrose, palatable NaCl at isotonic or hypotonic concentrations, and palatable fat emulsions can all evoke similar hedonic reactions [33], [102], [104]. Further, the affective taste reactivity pattern elicited by a particular taste can be altered by factors that also alter human palatability ratings, ranging from relevant appetite/satiety physiological states, to pharmacological opioid, endocannabinoid, etc. brain states of particular neuroanatomical structures, and types of neurobiological lesions [14], [26], [35], [69], [75], [84], [131]. Finally, specific brain microinjections, lesions, or optogenetic stimulations in forebrain structures can profoundly control taste-elicited ‘liking’ reactions as described below, which indicates a top-down or hierarchical control over brainstem circuitry that involves the entire brain. Altogether, these considerations indicate that the taste reactivity test reflects the affective (sensitive to homeostatic and learned cues), rather than merely a reflex or the sensory quality of a food reward.
In an effort to uncover the neural mechanisms of hedonic processing, taste reactivity has been used in conjunction with brain manipulations, such as pharmacological microinjections in particular structures. Using this coupled paradigm, Susana Peciña in the Berridge lab was able to demonstrate that a unique hedonic function was localized to a subregion of NAc medial shell; a 13 mm “hedonic hotspot” in the rostrodorsal quadrant of NAc medial shell [84]. Within the confines of the cubic-millimeter hotspot in shell, mu opioid receptor activation via microinjection of the mu agonist DAMGO [71] enhanced hedonic ‘liking’ reactions to a sweet sucrose solution, in addition to suppressing negative ‘disgust’ reactions to quinine [84], [106]. Within the NAc hotspot, mu opioid stimulation was found to double to triple the number of positive orofacial ‘liking’ reactions elicited by sweetness, in addition to dramatically stimulating intake of palatable food.
Outside the hotspot, the same opioid stimulation completely failed to increase ‘liking’ reactions, even though it increased intake just as much. In fact, at posterior locations in medial shell, opioid stimulation tended to oppositely suppress ‘liking’ reactions in a hedonic coldspot. However, at all sites in accumbens core and shell, DAMGO microinjections are equally effective at stimulating increases in food intake and in ‘wanting’ to obtain food, despite not enhancing ‘liking’ at most of those sites [7], [84], [85], [134]. Indeed, food intake can be stimulated at a number of related sites outside NAc, without enhancing ‘liking’ reactions, including the central nucleus of the amygdala [46], [68] and even regions of the ventral and dorsal neostriatum [39], [134]. Thus, opioid circuitry for ‘wanting’ to eat is more widely distributed throughout NAc and related structures than opioid circuitry for ‘liking’.
More recently, we have replicated the original mu opioid hotspot localization in the rostrodorsal quadrant of NAc shell for enhancements of sucrose ‘liking’ by DAMGO microinjections [30] (Fig. 1). Further, we have found evidence that the same anatomical site for the rostrodorsal mu hotspot can mediate opioid hedonic enhancements for delta stimulation (DPDPE) by three-fold and even kappa stimulation (U50488H) by two-fold, whereas no hedonic enhancements are produced at other locations in medial shell of NAc by either mu, delta or kappa stimulations [30] (Fig. 1). Oppositely instead, in a hedonic coldspot in the posterior half of medial shell, all three forms of opioid stimulation suppress hedonic reactions to sucrose, apparently reducing ‘liking’. However, each specific agonist had different anatomical patterns of effects on ‘wanting’ to eat in the sense of changing food intake despite their similar (rostral) enhancement hotspot versus (caudal) suppressive coldspot pattern of ‘liking’ effects [30] (Fig. 1). Mu stimulation increased eating at all sites throughout medial shell, as previously reported, both in the caudal coldspot and the rostral hotspot. However, delta stimulation only increased eating in the rostral hotspot but not at other sites, and kappa stimulation never consistently increased food intake at any site in medial shell. These differences speak again to the fundamental differences in mechanisms mediating ‘liking’ versus ‘wanting’, even within opioid systems contained in the medial shell of NAc. Related evidence has demonstrated endocannabinoid stimulation in the NAc hotspot and even GABAergic hyperpolarizations in the same hotspot can also enhance ‘liking’ reactions to sweet tastes [43], [69], [84], [91], [92].
All three types of opioid receptors couple to Gi subunits, subsequently leading to ERK activation and typically decreasing neuronal activity, which conceivably could be related to shared enhancement effects in the rostral hedonic hotspot and shared hedonic suppression effects in the caudal coldspot. However, though mu, delta and kappa pathways converge to activate ERK, they do so via different intracellular channels, which might possibly be relevant to how the three receptors have such different effects on motivated ‘wanting’ to eat reflected in food intake. However, the precise relation between intra-cellular mechanisms and ‘liking’/‘wanting’ effects still remains to be clarified.
By contrast to hedonic neurochemical manipulations, NAc dopamine stimulation by amphetamine microinjections within or outside the shell hotspot [106], [129], by genetic elevation of dopamine in the synapse (via knockdown of dopamine transporter in presynaptic dopamine neurons) [87], or by systemic amphetamine administration [119], [121], all consistently fail to enhance positive hedonic reactions to sweet tastes. Conversely, reduction of NAc dopamine by 6-OHDA lesions [17], [18], or by systemic dopamine blockade [86] all fail to reduce positive hedonic reactions. However, those same dopamine manipulations do potently alter motivated ‘wanting’ for the food rewards. Thus, unlike opioid or endocannabinoid neurotransmitters, dopamine in NAc does not appear to be a mechanism for hedonic ‘liking’, but rather is restricted to motivation ‘wanting’ roles regarding food rewards.
What anatomical basis might help explain the functional existence of an anatomically unique hotspot for opioid/endocannabinoid amplification of sensory pleasure, and why is it uniquely able to enhance hedonic impact to tastes, compared to other regions of NAc shell?
Recently, two independent groups of neuroanatomists have evaluated the anatomical connectivity patterns of the NAc rostrodorsal quadrant of medial shell, and found that this hotspot region differs from other subregions of medial shell (e.g., caudal shell). Thompson and Swanson [117] revealed, using a double injection of anterograde and retrograde tracers, that the rostrodorsal quadrant appears to belong to a different striato–pallido–hypothalamo–thalamo-cortical closed circuit loop from other subregions of medial shell. In other words, if one follows the projections from the rostrodorsal quadrant of medial shell along a point to point axis, one will end up back in the hotspot. This loop travels from the NAc hotspot to particular subregions of pallidum or hypothalamus, up to paraventricular nucleus of the thalamus, next passing through the infralimbic region of prefrontal cortex, and finally projecting back again to rostrodorsal medial shell. The subregions of each of these structures are distinct from the subregions visited by other parallel loops that pass through more posterior regions of medial shell. Exactly how many parallel loops pass through medial shell of NAc remains to be elucidated, but it seems clear now that there are at least two (visiting rostral vs caudal shell) and possibly additional loops that more finely dissect NAc shell into further subregions, each belonging to its own loop [117].
Similarly, Zahm and colleagues [133] recently found a related pattern of distinct connectivity that distinguishes the rostral hotspot from more caudal subregions of NAc medial shell. Those authors suggest that the rostral hotspot projects to particular regions of lateral preoptic area and lateral hypothalamus, and receives inputs from infralimbic (analogous to Brodmann's area 25) and other nearby regions of prefrontal cortex such as prelimbic and orbitofrontal cortex. They also suggest that the projection patterns of NAc rostral shell are similar to those of lateral septum, compared to the caudal shell, and that the rostral zone of medial shell is a unique transition region between NAc and lateral septum. In contrast, they suggest the caudal zone is a different transition region blending features of NAc and extended amygdala. While the Zahm et al. and the Thompson and Swanson studies differ on some points, the overall anatomical scheme presented by the two studies seems to agree that the circuitry belonging to the rostrodorsal hotspot quadrant of NAc medial shell is fundamentally different compared to the connectivity patterns of the rest of the medial shell, and that these anatomical differences may in part contribute to the hotspot's unique abilities to amplify the hedonic impact of taste sensations.
In addition to differences in projection patterns, there may also be other local neurobiological features of neurons in NAc medial shell that are relevant to hedonic contributions compared to other NAc components such as core. Meredith et al. [73] suggest that the local characteristics of neurons in NAc medial shell are different from other regions of NAc and striatum. For example, the projecting medium spiny neurons (MSNs) within medial shell are less spiny and smaller compared to NAc core or dorsal striatum. Furthermore, the distinction between different MSNs belonging to D1/dynorphin/direct pathway versus D2/enkephalin/indirect pathway, which is known from dorsal striatum, is somewhat diluted in NAc medial shell, where at least 17% of MSNs harbor both D1 and D2 receptors [22], [61]. Intriguingly, volume ratios of patch/matrix compartments in dorsal striatum (as delineated by mu opioid or calbindin binding) may also be flipped, or at the very least are not as cleanly split in nucleus accumbens [63], [72]. Although the roles of these neurobiological features is still unclear, some of these unique anatomical or cellular features of NAc medial shell might be relevant to its ability to generate hedonic functions that are fundamentally different from other regions of striatum.
The ventral pallidum (VP) receives the densest projections from NAc, compared to other target structures [77], [78]. Similar to NAc, VP also has been shown to be important for rewards [35], [70], [74], [104], [110], [114], [115], [130]. Also similar to NAc, the VP has been shown to contain a hedonic hotspot of its own [104].
In an initial microinjection mapping study of the VP hedonic hotspot, Kyle Smith in the Berridge lab made microinjections of DAMGO throughout the ventral pallidum and measured taste reactivity responses to sucrose and quinine, as well as changes in food intake [104]. Results showed that DAMGO microinjections in a roughly cubic-millimeter site of caudal VP enhanced hedonic reactions to sucrose, revealing a hedonic hotspot in the posterior half, as well as stimulating the motivation to eat more food. In behavioral and anatomical contrast to the posterior VP hotspot, microinjections into more rostral subregions of VP suppressed ‘liking’ reactions to sucrose and reduced food intake, indicating a VP opioid coldspot [104]. The caudal VP zone which enhanced hedonic reactions was slightly smaller (~ 0.83 mm) than the 13 mm NAc hotspot, although it is proportionally similar to the NAc hotspot when the relative size of the structures are taken into account. Thus, like NAc, the VP also appears to house a hedonic hotspot (but positioned caudally in VP, rather than rostrally as in NAc).
In addition to opioid signals, orexin signals in the posterior VP also can enhance the hedonic impact of sucrose [60]. This was found by performing microinjections of orexin-A directly into the VP hotspot or into the surrounding regions of lateral hypothalamus (lateral preoptic area) or into the extended amygdala. Chao-Yi Ho in the Berridge lab found that orexin microinjections enhanced ‘liking’ reactions when infused into the VP hotspot, but did not do so when infused into rostral ventral pallidum or into nearby structures such as lateral hypothalamus or extended amygdala [60]. Whether or not orexin also acts in the NAc hotspot to enhance hedonic impact is still unknown, but preliminary observations in our lab suggest that orexin may also perform a similar role in this NAc region as well (Castro and Berridge, unpublished observations).
During the 1960s and 70s, it was reported that lesions to LH would produce intense aphagia [23], [80], [99], [116]. In particular, Teitelbaum and Epstein [116] reported that LH lesions, in addition to disrupting eating and drinking behavior, also disrupted hedonic/appetitive reactions to sweet solutions and replaced them with aversive or ‘disgust’ reactions, which suggests a role for LH in affective processing and behavior. However, with the benefit of hindsight, it can be noted that those hypothalamic lesions were very large by modern standards, and the damage actually extended well outside the lateral hypothalamus. Additional structures were damaged, ranging from caudal ventral pallidum in a direction anterior to LH, and as far back as premammillary nucleus in a caudal direction. Subsequently Schallert and Whishaw [98] identified the anterior direction as most important, showing that electrolytic lesions only in anterior LH produced intense ‘disgust’ reactions to sucrose in addition to producing aphagia, whereas posterior LH lesions produced merely aphagia without any aversion. To more thoroughly localize the site of ‘disgust’ release, Cromwell and Berridge [35] made discrete excitotoxic lesions in VP (anterolateral to LH) or in nearby regions such as lateral hypothalamus and the preoptic area. They confirmed that lesions to all LH and VP sites produced aphagia, but found that only lesions that damaged VP produced the flip in affective responses to sucrose from ‘liking’ to ‘disgust’. Even anterior LH lesions did not release ‘disgust’ if VP was spared. Temporary inhibitions by muscimol microinjections into VP also have been reported to increase aversive reactions to sucrose [101]. More recently, a PhD dissertation study by Chao-Yi Ho, which mapped the increase of aversive reactions to sucrose, demonstrated that it was the VP hotspot in caudal VP that appears responsible for both lesion-induced ‘disgust’ and muscimol-induced ‘disgust’: sites for either in the posterior VP hotspot produced intense ‘disgust’ reactions to sucrose, whereas other sites in anterior VP as well as in anterior LH did not (as long as the posterior VP hotspot remained untouched) [59]. Such findings suggest that the VP hotspot in particular is especially important for generating normal hedonic impact, as well as for amplifying intense hedonic impact, since it is the only region in the brain known so far in which lesions not only suppress hedonic reactions, but also replaces them with aversive reactions to sweetness.
The larger anatomical zone in which VP is located was traditionally called the substantia innominata (SI), or unnamed substance. This was due to its lack of distinguishing features (as far as was then known), and the confusing nature of what constituted its borders, however the term substantia innominata was later criticized as too vague [57]. The VP boundaries reveal themselves when tissue is stained for enkephalin or substance P; VP produces more enkephalin and substance P than other nearby SI regions, and has distinct afferent and efferent patterns from that of the dorsally positioned globus pallidus [50], [54], marking it as a relatively distinct structure within SI.
Like the NAc hotspot, the VP hotspot in its posterior region has several unique characteristics that differ from other VP subregions that may contribute to its hedonic function. For example, Kupchik and Kalivas [66] showed that the electrophysiological signature of the neurons in VP change, depending on where they recorded along a rostrocaudal axis. Neurons in anterior VP included a mix of “Type I” and “Type II” neurons, whereas posterior VP was characterized solely by Type I neurons. Type I neurons are tonically active and easily excited, while Type II neurons have low basal firing rates, and require more stimulation to elicit an action potential. In addition to this, Type II neurons morphologically resemble the accumbens medium spiny neurons, whereas Type I neurons that predominate in posterior VP are relatively aspiny and are somewhat larger than Type II. Although it is still unclear how Type I and II neurons differ functionally, it is interesting to note that the change in neuron type follows the rostrocaudal functional difference between caudal VP hotspot and rostral VP coldspot sites.
In addition to the two forebrain hotspots of NAc and VP, there is also some evidence for a brainstem hedonic hotspot within the parabrachial nucleus (PBN) of the pons [108]. Although best known as a visceral/taste sensory relay [38], [79], the PBN has additional functions, including food intake [28], [40], [124], [127], establishing a conditioned taste aversion [28], [36], [130], and REM sleep [90], [120].
As noted above, Grill and Norgren [47], [49] pioneered the taste reactivity paradigm in order to compare normal and decerebrate (and thalamic or detelencephalic) rats. Mesencephalic decerebrate rats receive transections above the superior colliculus at the level of the midbrain, removing inputs from hypothalamus, thalamus and all telencephalic forebrain structures, and display no voluntary eating. However, despite the complete lack of spontaneous eating behavior, decerebrates show normal taste reactivity patterns to palatable sucrose or aversive quinine [47], [49]. Although decerebrate taste reactions are reflexive in nature, another potential implication of that finding is that even at the level of the brainstem, the beginnings of some elementary hedonic processing may be occurring [15].
To more directly assess brainstem hedonic function, Berridge [13] made systemic injections of chlordiazepoxide, a benzodiazepine drug that enhances hedonic reactions in normal rats as well as enhancing food intake [34], [121], into decerebrate rats and found that this benzodiazepine stimulation of the functional midbrain and hindbrain was still sufficient to enhance sucrose ‘liking’ reactions. Pecina and Berridge [83] then went on to show that fourth ventricular microinjections of diazepam into the brainstem fourth ventricle of intact rats also enhanced hedonic ‘liking’ reactions even at low doses that were ineffective in the forebrain lateral ventricles, again indicating that indeed there was a brainstem site capable of amplifying hedonic impact for normal animals.
Providing further localization of brainstem benzodiazepine mechanisms of food motivation, Higgs and Cooper [58] demonstrated that microinjections of a related benzodiazepine, midazolam, into the pontine parabrachial nucleus (PBN), but not nearby regions of brainstem, could significantly enhance food intake in non-deprived rats. Building on these findings, Soderpalm and Berridge [107] found that similar microinjections of midazolam into the lateral parabrachial nucleus of normal rats enhanced positive ‘liking’ taste reactivity patterns to sucrose taste, in addition to its hyperphagic effects, whereas microinjections into the hindbrain nucleus of the solitary tract or into midbrain ventral tegmental area did not.
Taken together, these studies implicate PBN benzodiazepine mechanisms in hedonic processing, extending the hedonic hotspot circuit to include brainstem, as well as forebrain, sites of action.
Recent work on the parabrachial nucleus has supported its role in food intake. For example, work by Simansky and colleagues showed that opioid and endocannabinoid stimulation within parabrachial nucleus also robustly increases consumption of palatable food [40], [124]. Further, endogenous opioid function within PBN appears to be required for food motivation, as infusions of naloxonazine completely prevented DAMGO induced hyperphagia [32].
More recently, Palmiter and colleagues have shown that the PBN interacts with hypothalamic mechanisms to control appetite [28], [126], [127], [128]. Wu et al. [127] showed that PBN neurons are normally inhibited by GABAergic projections from agouti-related protein (AgRP) neurons in the hypothalamic arcuate nucleus, and that destruction of AGRP neurons abolished eating. They then went on to show that the starvation effects they observed through AgRP neuron ablation were not due to increased melanocortin signaling [126], but rather to over-excitation of PBN from glutamate projections originating in the hindbrain nucleus of the solitary tract or serotonin neurons [128]. Similarly, Carter et al (2013b) showed that direct optogenetic stimulation of lateral PBN neurons that express calcitonin gene-related peptide also decreased food intake. Such mechanisms are potential candidates for future studies of PBN roles in hedonic impact.
The existence of multiple hedonic hotspots allows for the possibility that the hotspots interact and work together within a coordinated hedonic circuit. A functional circuit would not necessarily imply that the hotspots are all directly connected anatomically, since intermediary stops could be equally effective in creating a functional circuit. To determine whether at least a functional interaction existed, Smith and Berridge unbalanced the circuit by infusing DAMGO into one hotspot (e.g. NAc), while simultaneously infusing naloxone, an opioid antagonist, into another hotspot (e.g. VP) [105]. The guiding hypothesis was that if the simultaneous opioid neurotransmission is required in both hotspots, essentially creating unanimous opioid votes for enhancement in both sites, to increase ‘liking’ reactions to a palatable sweet solution, then blocking endogenous opioid signals in one hotspot should prevent exogenous opioid stimulation by DAMGO microinjection in the other from causing any hedonic enhancement. The results supported this hypothesis: opioid blockade in either the VP or NAc hotspot prevented DAMGO enhancement of positive ‘liking’ reactions in the other hotspot. Further supporting the functional relationship between the NAc and VP hotspots, it was also found that DAMGO activation in one hotspot enhanced Fos activity both locally and in the other hotspot, and in both directions, demonstrating that their functional interactions could be detected via neural markers of genomic transcription. It should be noted that although naloxone in VP prevented DAMGO-enhanced ‘liking’ in the NAc hotspot, enhancements of eating by NAc DAMGO were still robustly generated, suggesting again independent controls for hedonic ‘liking’ versus motivated ‘wanting’ of the same food reward.
In a further electrophysiological demonstration of NAc–VP hotspot interactions, Smith et al. [106] recorded taste reactivity responses and extracellular neuronal firing patterns in the VP hotspot during an intraoral infusion of sucrose. They found that neurons in the VP hotspot appeared to encode the impact of sucrose in neuronal firing, correlating with behavioral ‘liking’ reactions. This hedonic pattern manifested itself by steadily increasing the neural firing rate in a slow-onset but sustained the burst of action potentials, becoming evident during the first 1.5 s after the sweet taste was introduced, and sustaining this elevation in firing for the duration of the 10-s sucrose infusion. DAMGO microinjection into the NAc hotspot enhanced both behavioral hedonic taste reactivity to sucrose and the hedonic pattern of neural firing in VP elicited by the sweet taste. In behavioral contrast, amphetamine microinjections that potentiated dopamine transmission in the NAc hotspot only increased food intake and a more transient VP neural signal burst that encoded cue-triggered ‘wanting’, and correlated with amount of food eaten, but had no effect on behavioral taste reactivity ‘liking’ patterns or on the hedonic-encoding VP neural response to sucrose. Altogether, these results show that the VP and NAc hotspots interact to form a larger functional circuit that mediates the hedonic reaction to a palatable taste.
Although the evidence presented so far clearly indicates a functional relationship between the hotspots, it may be surprising to note that the NAc, VP and PBN hotspots do not have any known direct reciprocal anatomical connections between them. For example, although the NAc hotspot sends robust projections to the ventral pallidum, they are primarily directed toward rostromedial VP, and not to the posterior hotspot [50], [117], [122], [133]. Instead, the caudolateral core sends projections to the caudolateral VP region that contains the hotspot [50]. Beyond the NAc–VP projection, a NAc–PBN projection also exists. However, these NAc projections originate from the ventral half of medial shell, and not the dorsal half that primarily houses the rostral hotspot, leaving it unclear if NAc hotspot and PBN hotspot are directly connected [122] (Fig. 2).
An analysis of VP connections shows that it sends topographic efferents to NAc, so that anterior NAc connects with anterior VP, whereas posterior NAc connects with posterior VP [51]. This suggests that these two hotspots do not anatomically connect directly to each other (despite their clear functional relationship). Unlike NAc, VP does not project to PBN at all, although VP does reach other brainstem areas such as locus coeruleus and the raphe nuclei [51]. Similarly, PBN efferents do not appear to innervate NAc as far as is known [3], though they still might possibly interact, such as via lateral PBN efferents to the VP hotspot [96]. However, no study to our knowledge has systematically mapped PBN projections to caudal VP, leaving this connection somewhat unresolved [53], [76].
Altogether, an anatomical analysis of what is known of the current hotspot boundaries suggests that although the hotspots must work together, it cannot be via direct connections. If this is true, then hotspot activity is likely monitored and mediated by an as yet unidentified brain region that shares reciprocal connections with the hotspots.
Hunger modulates the hedonic impact of food through the phenomenon known as alliesthesia [24], [25]. One candidate mechanism to help mediate interactions between regulatory-hedonic circuitry is the hypothalamic orexin/hypocretin neurons, which both project to and receive direct inputs from all of the hotspots [4], [8], [50], [51], [56], [89], [132].
Orexin neurons relevant to reward appear to be localized within a small portion of perifornical and lateral hypothalamus [4], [9], [29], [55], [56], [88]. In other hypothalamic regions, such as in dorsomedial hypothalamus orexin/hypocretin neurons are mostly implicated in attention, arousal and sleep/wake cycles [1], [11], [27], [42], [45].
Reward-related orexin neurons in lateral hypothalamus are located just medial to the internal capsule and lateral to the perifornical area, heavily concentrated in the dorsal and magnocellular portions of LH. While a few orexin neurons can be found as far dorsal as zona incerta, most are located more ventrally (although many MCH-containing neurons are located in zona incerta), though still more dorsal than medial tuberal nucleus. The anterior–posterior extent of orexin neurons more or less coincides with the medial tuberal nucleus, which appears just after and ends just before the orexin field boundaries [8], [113].
Orexin is implicated in hunger alliesthesia [5], [20], [21], [41], [44], [67], [81], [97]. As mentioned above, recent work by Chao-Yi Ho in our lab found that direct orexin microinjections into the VP hotspot can selectively enhance sucrose ‘liking’ reactions [60], supporting the idea that activation of hypothalamic orexin projections to VP might enhance the hedonic impact of food.
We have recently conducted pilot studies of the role of LH-to-VP projections using optogenetic techniques to activate neurons [31]. Optogenetics has the special advantage of allowing stimulation of specific point-to-point projections [2], [10]. This potentially includes LH to VP projections (by putting virus in one location such as LH to infect neuron cell bodies but putting the stimulating optic fiber in a different location such as VP that receives axon terminals).
We recently infused an excitatory channelrhodopsin-2 virus into the reward-related orexin field of lateral hypothalamus, and implanted an optic fiber in the VP hotspot, which contains orexin/glutamate terminals from that field. We found that VP illumination of the orexin terminals from LH enhanced the hedonic ‘liking’ reactions to sucrose and also enhanced the motivation to consume food (measured by intake of palatable M&M candies) [31]. In contrast, direct illumination of LH neurons, by placing both optic fiber and virus in LH, increased only food intake, but did not increase sucrose ‘liking’, consistent with similar effects previously found from electrical stimulation of the LH [16], [35]. Finally, direct stimulation of VP neurons, by placing both illuminating optic fiber and virus microinjection in posterior VP, specifically enhanced hedonic reactions to sucrose, without increasing food intake, supporting VP hotspot involvement in amplifying hedonic impact [60], [104]. Taken together, these results indicate that neurons in the VP hotspot, and LH projections to the VP hotspot, are capable of amplifying sweetness hedonic impact.
Section snippets
Conclusion
Since the identification of localized hedonic hotspots in NAc, VP and brainstem, it has become increasingly clear that these hotspots are specialized generators of hedonic impact in food reward, and that they work together to form a larger functional hedonic circuit. Future work will extend this understanding, as well as the search for additional hotspots in the brain. Some potential targets for future searches include regions of the limbic prefrontal cortex, such as the orbitofrontal cortex
Acknowledgements
This manuscript is based on work presented during the 2013 Annual Meeting of the Society for the Study of Ingestive Behavior, July 30–August 3, 2013. Research described here was supported by the NIH grants MH63649 and DA015188 to KCB and the Hearing, Balance and Chemical Senses Training Grant DC00011 to DCC. The SSIB meeting was made possible in part by generous unrestricted donations from Ajinomoto North America, Inc, The Coca-Cola Company, GlaxoSmithKline Consumer Health Care, PepsiCo, Inc.,
References (134)
- et al.
Lateral hypothalamic orexin/hypocretin neurons: a role in reward-seeking and addiction
Brain Res
(2010) - et al.
Optogenetic tools for analyzing the neural circuits of behavior
Trends Cogn Sci
(2011) - et al.
Hypocretin/orexin in arousal and stress
Brain Res
(2010) Brainstem systems mediate the enhancement of palatability by chlordiazepoxide
Brain Res
(1988)Modulation of taste affect by hunger, caloric satiety, and sensory-specific satiety in the rat
Appetite
(1991)- et al.
What is the role of dopamine in reward: hedonic impact, reward learning, or incentive salience?
Brain Res Brain Res Rev
(1998) Mind versus metabolism in the control of food intake and energy balance
Physiol Behav
(2004)- et al.
The lateral hypothalamus as integrator of metabolic and environmental needs: from electrical self-stimulation to opto-genetics
Physiol Behav
(2011) - et al.
Fasting for 24 h improves nasal chemosensory performance and food palatability in a related manner
Appetite
(2012) - et al.
Role of orexin/hypocretin in reward-seeking and addiction: implications for obesity
Physiol Behav
(2010)
A naloxonazine sensitive (mu1 receptor) mechanism in the parabrachial nucleus modulates eating
Brain Res
Where does damage lead to enhanced food aversion: the ventral pallidum/substantia innominata or lateral hypothalamus?
Brain Res
Transfer of information about taste from the nucleus of the solitary tract to the parabrachial nucleus of the pons
Brain Res
Wake-promoting and sleep-suppressing actions of hypocretin (orexin): basal forebrain sites of action
Neuroscience
Co-existence of leptin- and orexin-receptors in feeding-regulating neurons in the hypothalamic arcuate nucleus—a triple labeling study
Peptides
Role of orexin input in the diurnal rhythm of locus coeruleus impulse activity
Brain Res
Involvement of mu opioid receptors in the amygdala in the control of feeding
Neuropharmacology
Neurological tests and behavioral deficits in chronic thalamic and chronic decerebrate rats
Brain Res
The taste reactivity test. II. Mimetic responses to gustatory stimuli in chronic thalamic and chronic decerebrate rats
Brain Res
The taste reactivity test. I. Mimetic responses to gustatory stimuli in neurologically normal rats
Brain Res
Organization of the output of the ventral striatopallidal system in the rat: ventral pallidal efferents
Neuroscience
Ramifications of the globus pallidus in the rat as indicated by patterns of immunohistochemistry
Neuroscience
Arousal and reward: a dichotomy in orexin function
Trends Neurosci
Substantia innominata: a notion which impedes clinical–anatomical correlations in neuropsychiatric disorders
Neuroscience
Hyperphagia induced by direct administration of midazolam into the parabrachial nucleus of the rat
Eur J Pharmacol
The ventral basal ganglia, a selection mechanism at the crossroads of space, strategy, and reward
Prog Neurobiol
Sucrose Bobs and Quinine Gapes: horse (Equus caballus) responses to taste support phylogenetic similarity in taste reactivity
Behav Brain Res
The functional neuroanatomy of the human orbitofrontal cortex: evidence from neuroimaging and neuropsychology
Prog Neurobiol
Pharmacological and anatomical evidence of selective mu, delta, and kappa opioid receptor binding in rat brain
Brain Res
Efferent connections and nigral afferents of the nucleus accumbens septi in the rat
Neuroscience
Brainstem mediates diazepam enhancement of palatability and feeding: microinjections into fourth ventricle versus lateral ventricle
Brain Res
Pimozide does not shift palatability: separation of anhedonia from sensorimotor suppression by taste reactivity
Pharmacol Biochem Behav
Selective Fos induction in hypothalamic orexin/hypocretin, but not melanin-concentrating hormone neurons, by a learned food-cue that stimulates feeding in sated rats
Neuroscience
Cholinergic and non-cholinergic afferents of the caudolateral parabrachial nucleus: a role in the long-term enhancement of rapid eye movement sleep
Neuroscience
Mapping brain circuits of reward and motivation: in the footsteps of Ann Kelley
Neurosci Biobehav Rev
Instant transformation of learned repulsion into motivational “wanting”
Curr Biol
The neural basis of drug craving: an incentive-sensitization theory of addiction
Brain Res Brain Res Rev
Efferent connections of the parabrachial nucleus in the rat
Brain Res
Neural substrates of awakening probed with optogenetic control of hypocretin neurons
Nature
Repeated cortico-striatal stimulation generates persistent OCD-like behavior
Science
Organization of the efferent projections from the pontine parabrachial area to the bed nucleus of the stria terminalis and neighboring regions: a PHA-L study in the rat
J Comp Neurol
Deconstruction of a neural circuit for hunger
Nature
Aversive stimuli differentially modulate real-time dopamine transmission dynamics within the nucleus accumbens core and shell
J Neurosci
Feeding induced by opioid stimulation of the ventral striatum: role of opiate receptor subtypes
J Pharmacol Exp Ther
Overlapping distributions of orexin/hypocretin- and dopamine-beta-hydroxylase immunoreactive fibers in rat brain regions mediating arousal, motivation, and stress
J Comp Neurol
Activation of a subpopulation of orexin/hypocretin-containing hypothalamic neurons by GABAA receptor-mediated inhibition of the nucleus accumbens shell, but not by exposure to a novel environment
Eur J Neurosci
Relation of consummatory responses and preabsorptive insulin release to palatability and learned taste aversions
J Comp Physiol Psychol
Wanting and liking: observations from the neuroscience and psychology laboratory
Inquiry (Oslo)
What psychological process mediates feeding evoked by electrical stimulation of the lateral hypothalamus?
Behav Neurosci
Taste reactivity analysis of 6-hydroxydopamine-induced aphagia: implications for arousal and anhedonia hypotheses of dopamine function
Behav Neurosci
Cited by (115)
An investigation into food choices among 5–12 years children in relation to sensory, nutritional, and healthy product cues
2023, Food Quality and PreferenceCrosstalk between Mu-Opioid receptors and neuroinflammation: Consequences for drug addiction and pain
2023, Neuroscience and Biobehavioral ReviewsIncrement in the consummatory response induced by reward delay: An animal model of binge-like eating episodes
2022, Learning and MotivationPavlovian occasion setting in human fear and appetitive conditioning: Effects of trait anxiety and trait depression
2021, Behaviour Research and Therapy