DNA targeting of rhinal cortex D2 receptor protein reversibly blocks learning of cues that predict reward

Liu, Zheng; Richmond, Barry J.; Murray, Elisabeth A.; Saunders, Richard C.; Steenrod, Sara C.; Stubblefield, Barbara; Montague, Deidra M.; Ginns, Edward I.

doi:10.1073/pnas.0403639101

Cited by 73 publications

(60 citation statements)

References 47 publications

(66 reference statements)

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“…The abundance and nature of observed gene expression differences, generally reflecting changes in discrete cell populations, suggest that phenotypic differences may be driven combinatorially by many small differences in the spatial regulation of gene expression. Functional implications for variations of expression patterns within structures noted in this study are suggested in reports that indicate a role for dopamine D2 receptor acting in entorhinal cortex during associative visual learning in nonhuman primates (17), as well as for variations in creativity correlated with receptor binding in the human thalamus (18). Furthermore, a recent study of striatopallidal neurons and dopaminergic regulation of GABAergic synaptic transmission highlights the functional relevance of the complex interplay of receptor expression, cell type, and circuitry within highly localized brain regions (19).…”

Section: Discussionmentioning

confidence: 93%

“…Therapeutics affecting the dopamine and serotonin systems are among the most commonly prescribed neuroactive drugs, covering a variety of indications ranging from depression and schizophrenia to movement disorders. The dopamine D2 receptor alone is a site of action for a number of therapeutics and has roles in locomotion, emotion, cognition, and drug abuse (17,20,21). Differences in individual responses to such drugs have been observed in humans (22) and previous studies have shown that C57 and DBA mice respond differently to drugs known to affect dopamine signaling (23).…”

Section: Discussionmentioning

confidence: 99%

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Divergent and nonuniform gene expression patterns in mouse brain

Morris

Royall

Bertagnolli

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

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Considerable progress has been made in understanding variations in gene sequence and expression level associated with phenotype, yet how genetic diversity translates into complex phenotypic differences remains poorly understood. Here, we examine the relationship between genetic background and spatial patterns of gene expression across seven strains of mice, providing the most extensive cellular-resolution comparative analysis of gene expression in the mammalian brain to date. Using comprehensive brainwide anatomic coverage (more than 200 brain regions), we applied in situ hybridization to analyze the spatial expression patterns of 49 genes encoding well-known pharmaceutical drug targets. Remarkably, over 50% of the genes examined showed interstrain expression variation. In addition, the variability was nonuniformly distributed across strain and neuroanatomic region, suggesting certain organizing principles. First, the degree of expression variance among strains mirrors genealogic relationships. Second, expression pattern differences were concentrated in higher-order brain regions such as the cortex and hippocampus. Divergence in gene expression patterns across the brain could contribute significantly to variations in behavior and responses to neuroactive drugs in laboratory mouse strains and may help to explain individual differences in human responsiveness to neuroactive drugs. T here are numerous and complex mechanisms by which genetic variation within or across species contributes to phenotypic diversity (1-3). The most appreciated and easily testable of these involve sequence modifications that alter the amino acid coding regions of genes and measurably affect protein function. Quantitative differences in transcript abundance, due to gene dosage or regulatory mutations have also been associated with phenotype (4-6). However, outside the realm of developmental biology and recent studies of copy number variation (7,8), the spatial distribution of gene expression within defined tissues and cell types remains relatively unexplored as a means by which genetic differences confer phenotypic differences.To investigate the relationship between spatial gene expression patterns and genetic background, we conducted a large-scale, systematic, brainwide survey of gene expression (9)

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Section: Discussionmentioning

confidence: 93%

Section: Discussionmentioning

confidence: 99%

Divergent and nonuniform gene expression patterns in mouse brain

Morris

Royall

Bertagnolli

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

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“…Fiducial markings as in Figure 4. cortex in which the D 2 receptor is crucial for learning the relation of the cue to the schedule states (Liu et al, , 2004. There is, however, a difficulty.…”

Section: Possible Origins Of the Signalsmentioning

confidence: 99%

Neuronal Signals in the Monkey Basolateral Amygdala during Reward Schedules

Sugase-Miyamoto¹,

Richmond²

2005

J. Neurosci.

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The amygdala is critical for connecting emotional reactions with environmental events. We recorded neurons from the basolateral complex of two monkeys while they performed visually cued schedules of sequential color discrimination trials, with both valid and random cues. When the cues were valid, the visual cue, which was present throughout each trial, indicated how many trials remained to be successfully completed before a reward. Seventy-six percent of recorded neurons showed response selectivity, with the selectivity depending on some aspects of the current schedule. After a reward, when the monkeys knew that the upcoming cue would be valid, 88 of 246 (36%) neurons responded between schedules, seemingly anticipating the receiving information about the upcoming schedule length. When the cue appeared, 102 of 246 (41%) neurons became selective, at this point encoding information about whether the current trial was the only trial required or how many more trials are needed to obtain a reward. These cue-related responses had a median latency of 120 ms (just between the latencies in inferior temporal visual area TE and perirhinal cortex). When the monkey was releasing a touch bar to complete the trial correctly, 71 of 246 (29%) neurons responded, with responses in the rewarded trials being similar no matter which schedule was ending, thus being sensitive to the reward contingency. Finally, 39 of 246 (16%) neurons responded around the reward. We suggest that basolateral amygdala, by anticipating and then delineating the schedule and representing reward contingency, provide contextual information that is important for adjusting motivational level as a function of immediate behavior goals.

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“…Richmond and his colleagues Shidara and Richmond, 2002;Shidara et al, 1998;Sugase-Miyamoto and Richmond, 2005;Bowman et al, 1996;Liu et al, 2004;Ravel and Richmond, 2006;La Camera and Richmond, 2008) have investigated many behavioral and neural aspects of an appealingly simple problem for monkeys that they call the reward schedule task. The task is illustrated in figure 1A.…”

Section: Introductionmentioning

confidence: 99%

Prospective and retrospective temporal difference learning

Dayan

2009

Network: Computation in Neural Systems

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A striking recent finding is that monkeys behave maladaptively in a class of tasks in which they know that reward is going to be systematically delayed. This may be explained by a malign Pavlovian influence arising from states with low predicted values. However, by very carefully analyzing behavioural data from such tasks, La Camera & Richmond (PLoS Computational Biology, doi:10.1371/journal.pcbi.1000131) observed the additional important characteristic that subjects perform differently on states in the task that are equal distances from the future reward, depending on what has happened in the recent past. The authors pointed out that this violates the definition of state value in the standard reinforcement learning models that are ubiquitous as accounts of operant and classical conditioned behavior; they suggested and analyzed an alternative temporal difference model in which past and future are melded. Here, we show that, in fact, a standard temporal difference model can actually exhibit the same behavior, and that this avoids deleterious consequences for choice. At the heart of the model is the average reward per step, which acts as a baseline for measuring immediate rewards. Relatively subtle changes to this baseline occasioned by the past can markedly influence predictions and thus behavior. Author SummaryWhen monkeys perform a sequence of identical tasks before getting a reward, they have been found to make many errors when they know the reward is far away. Oddly, these errors do not only depend on the number of trials to the future reward, they also depend, retrospectively, on the length of the sequence. A recent suggestion for modeling this result suggests an heuristic modification to an otherwise normative account. Here, we show an alternative way that the retrospective dependence could have arisen in a model based on estimating the average reward per step.

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DNA targeting of rhinal cortex D2 receptor protein reversibly blocks learning of cues that predict reward

Cited by 73 publications

References 47 publications

Divergent and nonuniform gene expression patterns in mouse brain

Divergent and nonuniform gene expression patterns in mouse brain

Neuronal Signals in the Monkey Basolateral Amygdala during Reward Schedules

Prospective and retrospective temporal difference learning

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