Genetic Polymorphisms Regulating Dopamine Signaling in the Frontal Cortex Interact to Affect Target Detection under High Working Memory Load

Frontal-dependent task performance is typically modulated by dopamine (DA) according to an inverted-U pattern, whereby intermediate levels of DA signaling optimizes performance. Numerous studies implicate trait differences in DA signaling based on differences in the catechol-O-methyltransferase (COMT) gene in executive function task performance. However, little work has investigated genetic variations in DA signaling downstream from COMT. One candidate is the dopamine- and cAMP-regulated phosphoprotein of molecular weight 32 kDa (DARPP-32), which mediates signaling through the DA D1-type receptor, the dominant DA receptor in the frontal cortex. Using an n-back task, we used signal detection theory to measure performance in a healthy adult population (n=97) genotyped for single nucleotide polymorphisms in the COMT (rs4680) and DARPP-32 (rs907094) genes. Correct target detection (hits), and false alarms were used to calculate d' measures for each working memory load (0-, 2-, and 3-back). At the highest load (3-back) only, we observed a significant COMT×DARPP-32 interaction, such that the DARPP-32 T/T genotype enhanced target detection in COMTValVal individuals, but impaired target detection in COMTMet carriers. These findings suggest that enhanced dopaminergic signaling via the DARPP-32 T allele aids target detection in individuals with presumed low frontal DA (COMTValVal) but impairs target detection in those with putatively higher frontal DA levels (COMTMet carriers). Moreover, these data support an inverted-U model with intermediate levels of DA signaling optimizing performance on tasks requiring maintenance of mental representations in working memory

Genetic influences on emotion/cognition interactions : from synaptic regulation to individual differences in working memory for emotional faces

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The relation among aging, dopamine-regulating genes, and neurocognition

When people are getting old, they often feel increasingly harder to concentrate, and become slower and more inflexible during tasks that involve focused attention, information maintenance in the face of distractions, and when fast switching according to changing goals is required. These cognitive functions are collectively referred to as working memory (WM). Both cross-sectional and longitudinal studies have reported WM impairment in aging. Moreover, aging is accompanied by alterations in brain structure, brain function, and dopaminergic neurotransmission. This thesis sought to link WM to brain structure, brain function, and dopamine (DA)-related genes in large samples of younger and older adults. The chief aims were to provide neural and genetic evidence to increase our understanding of the mechanisms of age-related deficits in WM. The DRD2/ANKK1-Taq1A polymorphism has been associated with DA D2 receptor densities in caudate. In study I, we investigated the effects of this polymorphism on grey-matter (GM) volume in striatum in older adults, and examined whether the genetic effect interacts with age. Results showed that the A allele of the DRD2/ANKK1-Taq1A polymorphism was associated with smaller GM volume in caudate and this effect was only observed in older adults (>72 years). The DRD2-C957T polymorphism has been linked to DA D2 receptor densities in both striatum and extrastriatal areas, such as in prefrontal cortex (PFC). In study II, we investigated the genetic effects of two DRD2 polymorphisms on WM functioning and examined how these effects may interact with adult age. In comparing younger and older adults, we found that the old had lower caudate activity in a highly demanding WM task. In addition, there were single and joint genetic effects of the two DRD2 polymorphisms on WM performance and frontostriatal brain activity. The genetic effects on brain function were observed in older, but not in younger adults, suggesting magnified genetic effects in aging. In study III, we related white-matter integrity with WM performance in a large sample across a wide age range. Results demonstrated that WM was associated with white-matter integrity in multiple tracts, indicating that WM functioning relies on global structural connections among multiple brain regions. Moreover, white-matter integrity could partially account for the age-related difference in WM. The COMT-Val158Met polymorphism has been associated with PFC DA levels. In this study, we found genetic effects of COMT on white-matter microstructure, suggesting a relation between dopaminergic function and white-matter integrity. In study IV, we investigated changes of white-matter integrity and WM performance using longitudinal data. We found that white-matter integrity declined across 10 years in the whole sample (25-80 years) and the decline was greater for older than for younger adults, reflecting a non-linear relation between age and white matter. More importantly, we found change – change associations of white-matter integrity and WM performance in several tracts including genu and body of corpus callosum and superior longitudinal fasciculus, suggesting that impaired WM performance in aging might reflect age-related decrease of white-matter integrity in these tracts. Collectively, these studies demonstrate age-related differences and changes in brain structure and brain function associated with impaired WM performance in aging. The findings support and extend previous work on the roles of DA in WM functioning and brain integrity in aging, and contribute to our understanding of neural and genetic correlates of WM, and how these are affected in aging

Effects of Acute Dopamine Precusor Depletion on Immediate Reward Selection Bias and Working Memory Depend on Catechol- O -methyltransferase Genotype

Little agreement exists as to acute dopamine (DA) manipulation effects on intertemporal choice in humans. We previously found that catechol-O-methyltransferase (COMT) Val158Met genotype predicts individual differences in immediate reward selection bias among adults. Moreover, we and others have shown that the relationship between COMT genotype and immediate reward bias is inverted in adolescents. No previous pharmacology studies testing DA manipulation effects on intertemporal choice have accounted for COMT genotype, and many have included participants in the adolescent age range (18–21) as adults. Moreover, many studies have included female subjects without strict cycle phase control, although recent evidence demonstrates that cyclic estradiol elevations interact with COMT genotype to affect DA-dependent cognition. These factors may have interacted with DA manipulations in past studies, potentially occluding detection of effects. Therefore, we predicted that among healthy adult males (ages 22–40), frontal DA tone, as indexed by COMT genotype, would interact with acute changes in DA signaling to affect intertemporal choice. In a double-blind, placebo-controlled design, we decreased central DA via administration of an amino acid beverage deficient in the DA precursors, phenylalanine and tyrosine (P/T[−]), and tested effects on immediate reward bias in a delay-discounting (DD) task and working memory (WM) in an n-back task. We found no main effect of beverage on DD or WM performance, but did find significant beverage*genotype effects. These results suggest that the effect of DA manipulations on DD depends on individual differences in frontal DA tone, which may have impeded some past efforts to characterize DA’s role in immediate reward bias in humans

Genetic Factors in the Regulation of Striatal and Extrastriatal Dopamine D2 Receptor Expression

Positron emission tomography (PET) studies on healthy individuals have revealed a marked interindividual variability in striatal dopamine D2 receptor density that can be partly accounted for by genetic factors. The examination of the extrastriatal lowdensity D2 receptor populations has been impeded by the lack of suitable tracers. However, the quantification of these D2 receptor populations is now feasible with recently developed PET radioligands. The objective of this thesis was to study brain neurobiological correlates of common functional genetic variants residing in candidate genes relevant for D2 receptor functioning. For this purpose, healthy subjects were studied with PET imaging using [11C]raclopride and [11C]FLB457 as radioligands. The candidate genes examined in this work were the human D2 receptor gene (DRD2) and the catechol-Omethyltransferase gene (COMT). The region-specific genotypic influences were explored by comparing D2 receptor binding properties in the striatum, the cortex and the thalamus. As an additional study objective, the relationship between cortical D2 receptor density and a cognitive phenotype i.e. verbal memory and learning was assessed. The main finding of this study was that DRD2 C957T genotype altered markedly D2 receptor density in the cortex and the thalamus whereas in the striatum the C957T genotype affected D2 receptor affinity, but not density. Furthermore, the A1 allele of the DRD2-related TaqIA polymorphism showed increased cortical and thalamic D2 receptor density, but had the opposite effect on striatal D2 receptor density. The DRD2 –141C Ins/Del or the COMT Val158Met genotypes did not change D2 receptor binding properties. Finally, unlike previously reported, cortical D2 receptor density did not show any significant correlation with verbal memory function. The results of this study suggest that the C957T and the TaqIA genotypes have region-specific neurobiological correlates in brain dopamine D2 receptor availability in vivo. The biological mechanisms underlying these findings are unclear, but they may be related to the region-specific regulation of dopamine neurotranssion, gene/receptor expression and epigenesis. These findings contribute to the understanding of the genetic regulation of dopamine and D2 receptor-related brain functions in vivo in man. In addition, the results provide potentially useful endophenotypes for genetic research on psychiatric and neurological disorders.Siirretty Doriast

Chronic Stress Effects on Prefrontal Cortical Structure and Function

Stressful life events have been implicated clinically in the pathogenesis of major depression, but the neural substrates that may account for this observation remain poorly understood. Attentional impairments symptomatic of depression are associated with structural and functional abnormalities in the prefrontal cortex. In three parallel rodent and human neuroimaging studies, this project assessed the effects of chronic stress on prefrontal cortical structure and function and the behavioral correlates of these changes. The first study used fMRI to elucidate the precise computational contributions of frontoparietal circuitry to attentional control in human subjects, using a task that could be adapted for rats. The results confirmed that the contributions of dorsolateral frontoparietal areas to visual attentional shifts could be dissociated from the regulatory influences of more ventrolateral areas on stimulus/response mappings, in a manner consistent with studies in animal models. They also indicated that anterior cingulate and posterior parietal cortex may act in concert to detect dissociable forms of information processing conflicts and signal to dorsolateral prefrontal cortex the need for increased attentional control. Stress-induced alterations in these regions and in the connections between them may therefore contribute to attentional impairments. The second study tested this hypothesis in rats by examining whether chronic stress effects on medial prefrontal (mPFC) and orbitofrontal (OFC) dendritic morphology underlie impairments in the behaviors that they subserve. Chronic stress induced a selective impairment in attentional control and a corresponding retraction of apical dendritic arbors in mPFC. By contrast, stress did not adversely affect reversal learning or OFC dendritic arborization. These results suggest that prefrontal dendritic remodeling may underlie the attentional deficits that are symptomatic of stress-related mental illness. The third study was designed to extend these findings to human subjects, using the techniques developed in Study 1. Accordingly, chronic stress predicted selective attentional impairments and alterations in prefrontal functional coupling that were reversible after four weeks. Together, these studies outline in broad strokes a mechanistic model by which chronic stress may predispose susceptible persons to the attentional impairments that are characteristic of major depression. Future studies will assess the roles of serotonin and neurotrophins in mediating these changes

Monoaminergic Neuropathology in Alzheimer's disease

Acknowledgments This work was supported by The Croatian Science Foundation grant. no. IP-2014-09-9730 (“Tau protein hyperphosphorylation, aggregation, and trans-synaptic transfer in Alzheimer’s disease: cerebrospinal fluid analysis and assessment of potential neuroprotective compounds”) and European Cooperation in Science and Technology (COST) Action CM1103 (“Stucture-based drug design for diagnosis and treatment of neurological diseases: dissecting and modulating complex function in the monoaminergic systems of the brain”). PRH is supported in part by NIH grant P50 AG005138.Peer reviewedPostprin

The interplay between a dietary preference for fat and sugar, gene expression in the dopaminergic system and executive cognition in humans

Obesity is a health issue of both individual and global importance. Evidence from rodent literature suggests that dietary preferences for fat and sugar might influence dopaminergic signaling in the brain and thus executive cognition. These diet-related changes could provide a mechanistic basis potentially explaining obesity-promoting behaviour. However, valid evidence for this link in humans is still scarce. This thesis aimed to add to this gap by studying dopamine-related gene expression profiles in peripheral cells and executive cognition in a human sample (n = 75). The results provide indications for an association between dietary preference and alterations in dopamingeric sigaling on a peripheral gene expression level even though the group differences were not statistically significant. A link to cognition could not be established with the methods applied. Yet, several targets for future research are suggested to further explore this interplay

Between destiny and disease: genetics and molecular pathways of CNS aging

Human brain aging is associated with robust "normal" functional, structural, and molecular changes that underlie changes in cognition, memory, mood and motor function, amongst other processes. Normal aging is also a requirement for onset of many neurological diseases, ranging from later onset neurodegenerative diseases such as Alzheimer's(AD) and Parkinson's diseases(PD), to earlier onset psychiatric disorders such as bipolar disorder(BPD) and schizophrenia(SCHZ). Understanding the molecular mechanisms and genetic underpinnings of normal age-related brain changes would have profound consequences for prevention and treatment of age-related impairments and disease. Here I introduce current knowledge of these functional changes, their structural and molecular underpinnings, their genetic modulators, and the contribution of normal aging to age-related neurological disease. I then present my contribution to this field in the form of three papers on genetic modulation of mammalian brain molecular aging. These studies demonstrate and investigate mechanisms underlying the causal modulation of molecular brain aging rates by Brain Derived Neurotrophic Factor (BDNF) and Serotonin (5-HT) in knock-out (KO) mice, and associative modulation by the putative longevity gene, Sirtuin 5, in humans (novel low-expressing promoter polymorphism (Sirt5prom2)). In humans we additionally investigate the potential mechanism(s) underlying neurological disease gating by normal aging, providing supporting evidence for molecular aging being a genetically controlled "transcriptional program" that progressively promotes age-regulated neurological diseases. In the discussion, I place these studies in a broader context within the field, detailing their implications and future directions