scispace - formally typeset
Search or ask a question
Journal ArticleDOI

An obesity-associated risk allele within the FTO gene affects human brain activity for areas important for emotion, impulse control and reward in response to food images.

Lyle Wiemerslage1, Emil K. Nilsson1, Linda Solstrand Dahlberg1, Fia Ence-Eriksson1, Sandra Castillo1, Anna L. Larsen1, Simon B. A. Bylund1, Pleunie S. Hogenkamp1, Gaia Olivo1, Marcus Bandstein1, Olga E. Titova1, Elna-Marie Larsson1, Christian Benedict1, Samantha J. Brooks2, Helgi B. Schiöth1 
Uppsala University1, University of Cape Town2
21 Feb 2016-European Journal of Neuroscience (Wiley)-Vol. 43, Iss: 9, pp 1173-1180
TL;DR: The results suggest that the two genotypes are associated with differential neural processing of food images, which may influence weight status through diminished impulse control and reward processing.
Abstract: Understanding how genetics influences obesity, brain activity and eating behaviour will add important insight for developing strategies for weight-loss treatment, as obesity may stem from different causes and as individual feeding behaviour may depend on genetic differences. To this end, we examined how an obesity risk allele for the FTO gene affects brain activity in response to food images of different caloric content via functional magnetic resonance imaging (fMRI). Thirty participants homozygous for the rs9939609 single nucleotide polymorphism were shown images of low- or high-calorie food while brain activity was measured via fMRI. In a whole-brain analysis, we found that people with the FTO risk allele genotype (AA) had increased activity compared with the non-risk (TT) genotype in the posterior cingulate, cuneus, precuneus and putamen. Moreover, higher body mass index in the AA genotype was associated with reduced activity to food images in areas important for emotion (cingulate cortex), but also in areas important for impulse control (frontal gyri and lentiform nucleus). Lastly, we corroborate our findings with behavioural scales for the behavioural inhibition and activation systems. Our results suggest that the two genotypes are associated with differential neural processing of food images, which may influence weight status through diminished impulse control and reward processing.

Summary (4 min read)

Jump to: [INTRODUCTION][FTO Associated Brain Activity 5][Participants][Behavioral Questionnaires][Preprocessing of fMRI data][Statistical Analysis][RESULTS][Differential patterns of behavior for each FTO genotype depending on body-mass index.][DISCUSSION][FTO Associated Brain Activity 14] and [B)]

INTRODUCTION

  • Several different FTO single nucleotide polymorphisms (SNPs) are associated with a higher body mass index (BMI) (Sällman Almén et al., 2013; Scuteri et al., 2007a) , and higher energy intake (Speakman, 2013) .
  • Moreover, experiments in rodents show that changes in FTO expression levels in the hypothalamus affect feeding behavior (Frederiksen, Skakkebaek, & Andersson, 2007; Olszewski et al., 2009; Tung et al., 2010) .
  • Personality scales for the Behavioral Inhibition System (BIS) and Behavioral Activation System (BAS), which measure punishment and reward sensitivity respectively, are two such tools which correlate with inactivity and poor diet (Carver & White, 1994; Dietrich, Federbusch, Grellmann, Villringer, & Horstmann, 2014; Meule, 2013; Voigt et al., 2009) .

FTO Associated Brain Activity 5

  • To date, however, few fMRI studies have examined how genetic profile is associated with brain responses to food in obesity.
  • A recent study found that people with the FTO risk allele for rs8050136 had reduced activity in the right prefrontal cortex while viewing food images in a postprandial state, but not while fasting (Heni et al., 2014) .
  • Notably, their cohort of participants had a normal BMI with no obese participants.
  • Against this background, the authors explore for the first time the association between FTO genotype, BMI, and neural responses to food images of either low-or high-calorie content.

Participants

  • Prior to any experimental procedures, all participants gave written informed consent to the study which conformed to the Declaration of Helsinki and approved by the local ethics committee.
  • Genotyping of the FTO single nucleotide polymorphism (SNP) rs9939609 was performed with a pre-designed Taqman single-nucleotide polymorphism genotyping assay (Applied Biosystems, Foster City, USA) and an ABI7900 genetic analyzer with SDS 2.2 software at the Uppsala Genome Center (http://www.genpat.uu.se/node462).
  • Only homozygous participants were included in the study.
  • Hunger ratings were also assessed on a 1-10 scale with higher numbers indicating greater feelings of hunger.

Behavioral Questionnaires

  • Clinical measures for punishment sensitivity and reward-seeking behavior were acquired using the Behavioral Inhibition System (BIS) and Behavioral Activation System (BAS) questionnaires (Carver & White, 1994) .
  • Each item was represented by a statement, where the participant indicated how much s/he agreed or FTO Associated Brain Activity 7 disagreed on a four-point scale.
  • The BIS included only one scale, evaluating the reactions to the anticipation of punishment and anxiety, while the BAS included three subscales: Drive, which represents the pursuit of desired goals; Fun Seeking, which evaluates the desire for new rewards and impulsivity; and Reward Responsiveness, which focuses on positive reactions anticipating rewards.

Preprocessing of fMRI data

  • All preprocessing steps were performed using software package Statistical Parametric Mapping (SPM, version 8, http://www.fil.ion.ucl.ac.uk/spm/), implemented in MATLAB (version R2014a, 11 FEB 2014 .
  • The images were realigned and estimated to remove movement artefacts in the data.
  • EPI images were further matched with the structural image using coregistration.
  • The anatomical image was segmented to strip away unnecessary tissue in the images.
  • Tissue probability maps were introduced in the segmentation step to differentiate between gray matter, white matter and cerebrospinal fluid in each individual.

Statistical Analysis

  • All fMRI statistical analysis was performed using the same versions of SPM and MATLAB listed in preprocessing steps.
  • For all whole-brain results, a family wise error FTO Associated Brain Activity 9 (FWE) corrected significance level was set at p < 0.05 to correct for multiple testing.
  • This contrast was then tested using a between-groups t-test followed by directional post-hoc comparisons as well as with a multiple regression analysis testing for interactions between genotype and BMI, BIS, or BAS individually.
  • Bilateral masks of such areas were produced using the Wake Forest University Pickatlas toolbox (Maldjian, Laurienti, Kraft, & Burdette, 2003) within SPM.
  • Results for the PCA were considered significant if the percentage of inertia summing from the two largest eigenvalues exceeded values listed in a significance table based on 10,000 analyses with similar numbers of individuals and independent variables (Lê et al., 2008) .

RESULTS

  • The obesity-associated FTO SNP rs9939609, is associated with increased activity in response to food images.
  • BOLD signals were measured as participants were shown images of low-calorie (LC) food, high-calorie (HC) food, or control images in a block design format.
  • Areas included the posterior cingulate cortex (PCC), cingulate gyrus, cuneus, and precuneus (Table 2 ).
  • A multiple regression analysis found an interaction between genotype and BMI, post-hoc comparisons found significant clusters for the AA genotype while BMI was decreasing in the PCC, cingulate gyrus, middle occipital gyrus, and precuneus (Supplementary Table 1 ).
  • Within the t-test comparison between genotypes, a significant cluster showing greater activity in the AA genotype was FTO Associated Brain Activity 11 found in the putamen after performing a small-volumes correction using a 6 mmradius sphere over the lowest FWE-corrected p-value in the cluster (Table 2 ).

Differential patterns of behavior for each FTO genotype depending on body-mass index.

  • The authors next tested if behavioral questionaires corrobarated the findings from the imaging experiments.
  • The authors then performed a principle component analysis within each genotype using the BIS and the three BAS subscales (Drive, Fun Seeking, and Reward Responsiveness) as variables of interest with BMI as a quantitative supplementary variable.
  • For both analyses, all the variables of interest were well projected and the first two dimensions accounted for ≈80% of the variablity (considered significant based on critera listed in methods under statistical analysis subheading, 81.4 > 80.0 for the AA group and 79.2 > 76.5 in the TT group).
  • Moreover, the variables of interest projected to the same quandrants except for the Drive and Fun Seeking subscales, which were switched between the two different genotypes.
  • Furthermore, the authors followed up the association between the BIS and BMI using a multiple regression analysis testing if BIS scores could be predicted by genotype, BMI, or their interaction.

DISCUSSION

  • The authors examined whether an obesity-associated genotype affects the neural processing of food images with different caloric content and to what extent body-mass index (BMI) is an important factor.
  • The authors found the AA genotype had increased brain activity compared to the TT genotype when viewing food images with different caloric contents, specifically in areas important for emotion (cingulate gyrus), memory, and self-image (cuneus and precuneus) and reward .
  • Thus, discrimination between HC and LC foods may be handled differently for each genotype depending on BMI.
  • Next, the authors corroborate their findings in the imaging study with personality questionnaires examining behavioral characteristics related to impulsivity and rewardprocessing: namely the Behavioral Inhibition System (BIS) and Behavioral Activation System (BAS) scales.
  • The authors found that the BIS as well as subscales of the BAS correlated with BMI oppositely in each genotype.

FTO Associated Brain Activity 14

  • In between-groups comparisons, as well as multiple regression analysis, the authors found significant clusters of brain activity when testing a contrast for caloric discrimination (HC food images opposed to LC food images).
  • Specifically, the authors found increased neural activation in the AA genotype compared to the TT genotype within the posterior cingulate cortex (PCC), cingulate gyrus, cuneus and precuneus.
  • The PCC is a well-connected and multifunctional brain area associated with emotional processing, and a central node in the default mode network (DMN): involved in arousal/awareness, balancing external and internal thought, and emotion (Leech & Sharp, 2014) .
  • Thus, the AA genotype in their cohort confirms previous reports equating impulsivity with obesity/overeating (Meule, 2013) specifically in one study which also found a negative correlation between BIS and BMI in males (Dietrich et al., 2014) .
  • In conclusion, their findings offer insight into the relationship between FTO, obesity, and brain activity; and suggest that overweight/obese populations have different attitudes and functional processing for food images depending on genetic background.

B)

  • A region of interest analysis found a significant cluster within the putamen after a smallvolumes correction.
  • The BIS evaluates inhibitory behavior in the anticipation of punishment and anxiety, while the BAS included three subscales: Drive, which represents the pursuit of desired goals; Fun Seeking, which evaluates the desire for new rewards and impulsivity; and Reward Responsiveness, which focuses on positive reactions anticipating rewards.
  • The behavioral variables were all well projected in each group.
  • A) variables factor map for the AA genotype.
  • BMI was positively correlated with BIS and negatively correlated with the BAS Fun Seeking subscale.

Did you find this useful? Give us your feedback

Figures (1)

Content maybe subject to copyright    Report

Wiemerslage, L, Nilsson, EK, Solstrand Dahlberg, L, Ence-Eriksson, F, Castillo,
S, Larsen, AL, Bylund, SBA, Hogenkamp, PS, Olivo, G, Bandstein, M, Titova,
OE, Larsson, E-M, Benedict, C, Brooks, SJ and Schiöth, HB
An obesity-associated risk allele within the FTO gene affects human brain
activity for areas important for emotion, impulse control and reward in
response to food images.
http://researchonline.ljmu.ac.uk/id/eprint/9287/
Article
LJMU has developed LJMU Research Online for users to access the research output of the
University more effectively. Copyright © and Moral Rights for the papers on this site are retained by
the individual authors and/or other copyright owners. Users may download and/or print one copy of
any article(s) in LJMU Research Online to facilitate their private study or for non-commercial research.
You may not engage in further distribution of the material or use it for any profit-making activities or
any commercial gain.
The version presented here may differ from the published version or from the version of the record.
Please see the repository URL above for details on accessing the published version and note that
access may require a subscription.
For more information please contact researchonline@ljmu.ac.uk
http://researchonline.ljmu.ac.uk/
Citation (please note it is advisable to refer to the publisher’s version if you
intend to cite from this work)
Wiemerslage, L, Nilsson, EK, Solstrand Dahlberg, L, Ence-Eriksson, F,
Castillo, S, Larsen, AL, Bylund, SBA, Hogenkamp, PS, Olivo, G, Bandstein,
M, Titova, OE, Larsson, E-M, Benedict, C, Brooks, SJ and Schiöth, HB (2016)
An obesity-associated risk allele within the FTO gene affects human brain
LJMU Research Online
http://researchonline.ljmu.ac.uk/
FTO Associated Brain Activity 1
Title 1
An obesity-associated risk allele within the FTO gene affects brain activity for areas 2
important for emotion, impulse control, and reward in response to food images. 3
4
Running Title 5
FTO Associated Brain Activity 6
7
Author names and affiliation 8
Lyle Wiemerslage*
§
, Emil K Nilsson
§
, Linda Solstrand Dahlberg
§
, Fia Ence-Eriksson
§
, 9
Sandra Castillo
§
, Anna L Larsen
§
, Simon BA Bylund
§
, Pleunie S Hogenkamp
§
, Gaia 10
Olivo
§
, Marcus Bandstein
§
, Olga E Titova
§
, Elna-Marie Larsson
, Christian Benedict
§
, 11
Samantha J Brooks
, Helgi B Schiöth
§
12
13
Uppsala University § 14
Department of Neuroscience, Functional Pharmacology 15
Biomedicinska Centrum (BMC) 16
Husargatan 3, Box 593 17
751 24 Uppsala, Sweden 18
19
Section of Neuroradiology 20
Department of Radiology, Uppsala University 21
Akademiska Sjukhuset 22
751 85 Uppsala, Sweden 23
24
University of Cape Town 25
Department of Psychiatry 26
Old Groote Schuur Hospital 27
J2 Building 28
Anzio Road 29
Observatory, Cape Town, South Africa. 30
31
Corresponding author 32
Uppsala University * 33
Department of Neuroscience, Functional Pharmacology 34
Biomedicinska Centrum (BMC) 35
FTO Associated Brain Activity 2
Husargatan 3, Box 593 36
751 24 Uppsala, Sweden 37
lyle.wiemerslage@neuro.uu.se 38
39
Number of: 40
Figures = 3 41
Tables = 1 42
Words: 43
o Abstract = 197 44
o Introduction = 565 45
o Entire Manuscript (excluding references and figure legends) = 3,972 46
47
Keywords: 48
FTO, fMRI, SNP, obesity, food 49
50
Conflict of Interest: 51
The authors declare no conflicts of interest. 52
FTO Associated Brain Activity 3
ABSTRACT 53
Understanding how genetics influences obesity, brain activity, and eating behavior will 54
add important insight for developing strategies for weight-loss treatment, as obesity may stem 55
from different causes and as individual feeding behavior may depend on genetic differences. 56
To this end, we examined how an obesity risk-allele for the FTO gene affects brain activity in 57
response to food images of different caloric content via fMRI. 30 participants homozygous 58
for the rs9939609 single nucleotide polymorphism were shown images of low- or high-calorie 59
food while brain activity was measured via fMRI. In a whole-brain analysis, we found that 60
people with the FTO risk-allele genotype (AA) had increased activity than the non-risk (TT) 61
genotype in the posterior cingulate, cuneus, precuneus, and putamen. Moreover, higher BMI 62
in the AA genotype was associated with reduced activity to food images in areas important for 63
emotion (cingulate cortex), but also in areas important for impulse control (frontal gyri and 64
lentiform nucleus). Lastly, we corroborate our findings with behavioral scales for the 65
behavioral inhibition and activation systems (BIS/BAS). Our results suggest that the two 66
genotypes are associated with differential neural processing of food images, which may 67
influence weight status through diminished impulse control and reward processing. 68
69
Keywords: 70
fMRI, FTO, SNP, BMI, food images, obesity 71
Citations
More filters
Journal ArticleDOI
Brain Insulin Resistance at the Crossroads of Metabolic and Cognitive Disorders in Humans

[...]

Stephanie Kullmann, Martin Heni, Manfred Hallschmid, Andreas Fritsche, Hubert Preissl, Hans-Ulrich Häring 
01 Oct 2016-Physiological Reviews
TL;DR: The most prominent factors associated with brain insulin resistance are elaborate, i.e., obesity, T2D, genes, maternal metabolism, normal aging, inflammation, and dementia, and on their roles regarding causes and consequences.
Abstract: Ever since the brain was identified as an insulin-sensitive organ, evidence has rapidly accumulated that insulin action in the brain produces multiple behavioral and metabolic effects, influencing eating behavior, peripheral metabolism, and cognition. Disturbances in brain insulin action can be observed in obesity and type 2 diabetes (T2D), as well as in aging and dementia. Decreases in insulin sensitivity of central nervous pathways, i.e., brain insulin resistance, may therefore constitute a joint pathological feature of metabolic and cognitive dysfunctions. Modern neuroimaging methods have provided new means of probing brain insulin action, revealing the influence of insulin on both global and regional brain function. In this review, we highlight recent findings on brain insulin action in humans and its impact on metabolism and cognition. Furthermore, we elaborate on the most prominent factors associated with brain insulin resistance, i.e., obesity, T2D, genes, maternal metabolism, normal aging, inflammation, and dementia, and on their roles regarding causes and consequences of brain insulin resistance. We also describe the beneficial effects of enhanced brain insulin signaling on human eating behavior and cognition and discuss potential applications in the treatment of metabolic and cognitive disorders.

349 citations

Cites background from "An obesity-associated risk allele w..."

  • ...Also functionally, the FTO risk allele affects brain areas important for reward processing and food-cue reactivity (215, 263, 389)....

    [...]

Journal ArticleDOI
Food-Related Impulsivity in Obesity and Binge Eating Disorder—A Systematic Update of the Evidence

[...]

Katrin Elisabeth Giel, Martin Teufel1, Florian Junne2, Stephan Zipfel2, Kathrin Schag 
University of Duisburg-Essen1, University of Tübingen2
27 Oct 2017-Nutrients
TL;DR: The synthesis of the latest evidence consolidates conclusions drawn in the initial systematic review that BED represents a distinct phenotype within the obesity spectrum that is characterized by increased impulsivity.
Abstract: The specific eating pattern of Binge Eating Disorder (BED) patients has provoked the assumption that BED might represent a phenotype within the obesity spectrum that is characterized by increased impulsivity. Following the guidelines of the PRISMA statement (preferred reporting items for systematic reviews and meta-analyses), we here provide a systematic update on the evidence on food-related impulsivity in obese individuals, with and without BED, as well as normal-weight individuals. We separately analyzed potential group differences in the impulsivity components of reward sensitivity and rash-spontaneous behavior. Our search resulted in twenty experimental studies with high methodological quality. The synthesis of the latest evidence consolidates conclusions drawn in our initial systematic review that BED represents a distinct phenotype within the obesity spectrum that is characterized by increased impulsivity. Rash-spontaneous behavior in general, and specifically towards food, is increased in BED, while food-specific reward sensitivity is also increased in obese individuals without BED, but potentially to a lesser degree. A major next step for research entails the investigation of sub-domains and temporal components of inhibitory control in BED and obesity. Based on the evidence of impaired inhibitory control in BED, affected patients might profit from interventions that address impulsive behavior.

195 citations

Journal ArticleDOI
Fat Mass and Obesity-associated (FTO) Protein Regulates Adult Neurogenesis.

[...]

Liping Li1, Liping Li2, Liqun Zang2, Liqun Zang1, Feiran Zhang3, Junchen Chen2, Junchen Chen1, Hui Shen2, Hui Shen1, Liqi Shu3, Liqi Shu4, Feng Liang2, Feng Liang1, Chunyue Feng1, Deng Chen5, Huikang Tao1, Tianlei Xu3, Ziyi Li3, Yunhee Kang3, Hao Wu3, Lichun Tang6, Pumin Zhang6, Peng Jin3, Qiang Shu1, Xuekun Li1, Xuekun Li2 
Boston Children's Hospital1, Zhejiang University2, Emory University3, George Washington University4, Peking Union Medical College5, Protein Sciences6
01 Jul 2017-Human Molecular Genetics
TL;DR: It is shown that FTO is expressed in adult neural stem cells and neurons and displays dynamic expression during postnatal neurodevelopment and this results suggest FTO plays important roles in neurogenesis, as well as in learning and memory.
Abstract: Fat mass and obesity-associated gene (FTO) is a member of the Fe (II)- and oxoglutarate-dependent AlkB dioxygenase family and is linked to both obesity and intellectual disability. The role of FTO in neurodevelopment and neurogenesis, however, remains largely unknown. Here we show that FTO is expressed in adult neural stem cells and neurons and displays dynamic expression during postnatal neurodevelopment. The loss of FTO leads to decreased brain size and body weight. We find that FTO deficiency could reduce the proliferation and neuronal differentiation of adult neural stem cells in vivo, which leads to impaired learning and memory. Given the role of FTO as a demethylase of N6-methyladenosine (m6A), we went on to perform genome-wide m6A profiling and observed dynamic m6A modification during postnatal neurodevelopment. The loss of FTO led to the altered expression of several key components of the brain derived neurotrophic factor pathway that were marked by m6A. These results together suggest FTO plays important roles in neurogenesis, as well as in learning and memory.

194 citations

Journal ArticleDOI
Genetic risk for obesity predicts nucleus accumbens size and responsivity to real-world food cues

[...]

Kristina M. Rapuano1, Amanda L. Zieselman1, William M. Kelley1, James D. Sargent1, Todd F. Heatherton1, Diane Gilbert-Diamond1 
Dartmouth College1
03 Jan 2017-Proceedings of the National Academy of Sciences of the United States of America
TL;DR: It is shown that children genetically at risk for obesity exhibit stronger reward-related responses to real-world food cues in the nucleus accumbens, a brain area canonically associated with reward processing, which may contribute to unhealthy eating behaviors later in life.
Abstract: Obesity is a major public health concern that involves an interaction between genetic susceptibility and exposure to environmental cues (e.g., food marketing); however, the mechanisms that link these factors and contribute to unhealthy eating are unclear. Using a well-known obesity risk polymorphism (FTO rs9939609) in a sample of 78 children (ages 9-12 y), we observed that children at risk for obesity exhibited stronger responses to food commercials in the nucleus accumbens (NAcc) than children not at risk. Similarly, children at a higher genetic risk for obesity demonstrated larger NAcc volumes. Although a recessive model of this polymorphism best predicted body mass and adiposity, a dominant model was most predictive of NAcc size and responsivity to food cues. These findings suggest that children genetically at risk for obesity are predisposed to represent reward signals more strongly, which, in turn, may contribute to unhealthy eating behaviors later in life.

76 citations

Journal ArticleDOI
The role of mRNA m 6 A methylation in the nervous system

[...]

Jiashuo Li1, Xinxin Yang1, Zhipeng Qi1, Yanqi Sang1, Yanan Liu1, Bin Xu1, Wei Liu1, Zhaofa Xu1, Yu Deng1 
China Medical University (PRC)1
20 Aug 2019-Cell & Bioscience
TL;DR: The research progress and related mechanisms of the role of mRNA m6A methylation in the nervous system from the aspects of neural stem cells, learning and memory, brain development, axon growth and glioblastoma are reviewed.
Abstract: Epitranscriptomics, also known as “RNA epigenetics”, is a chemical modification for RNA regulation. Ribonucleic acid (RNA) methylation is considered to be a major discovery following the deoxyribonucleic acid (DNA) and histone methylation. Messenger RNA (mRNA) methylation modification accounts for more than 60% of all RNA modifications and N6-methyladenosine (m6A) is known as one of the most common type of eukaryotic mRNA methylation modifications in current. The m6A modification is a dynamic reversible modification, which can directly or indirectly affect biological processes, such as RNA degradation, translation and splicing, and can play important biological roles in vivo. This article introduces the mRNA m6A methylation modification enzymes and binding proteins, and reviews the research progress and related mechanisms of the role of mRNA m6A methylation in the nervous system from the aspects of neural stem cells, learning and memory, brain development, axon growth and glioblastoma.

69 citations

References
More filters
Journal ArticleDOI
Obesity and addiction: neurobiological overlaps.

[...]

Nora D. Volkow1, Gene-Jack Wang2, Dardo Tomasi2, Ruben Baler1
National Institute on Drug Abuse1, Brookhaven National Laboratory2
01 Jan 2013-Obesity Reviews
TL;DR: For instance, this paper found that both obese and drug-addicted individuals suffer from impairments in dopaminergic pathways that regulate neuronal systems associated not only with reward sensitivity and incentive motivation, but also with conditioning, self-control, stress reactivity and interoceptive awareness.
Abstract: Drug addiction and obesity appear to share several properties. Both can be defined as disorders in which the saliency of a specific type of reward (food or drug) becomes exaggerated relative to, and at the expense of others rewards. Both drugs and food have powerful reinforcing effects, which are in part mediated by abrupt dopamine increases in the brain reward centres. The abrupt dopamine increases, in vulnerable individuals, can override the brain's homeostatic control mechanisms. These parallels have generated interest in understanding the shared vulnerabilities between addiction and obesity. Predictably, they also engendered a heated debate. Specifically, brain imaging studies are beginning to uncover common features between these two conditions and delineate some of the overlapping brain circuits whose dysfunctions may underlie the observed deficits. The combined results suggest that both obese and drug-addicted individuals suffer from impairments in dopaminergic pathways that regulate neuronal systems associated not only with reward sensitivity and incentive motivation, but also with conditioning, self-control, stress reactivity and interoceptive awareness. In parallel, studies are also delineating differences between them that centre on the key role that peripheral signals involved with homeostatic control exert on food intake. Here, we focus on the shared neurobiological substrates of obesity and addiction.

553 citations

Journal ArticleDOI
Brain Mechanisms of Propofol-Induced Loss of Consciousness in Humans: a Positron Emission Tomographic Study

[...]

Pierre Fiset1, Tomáš Paus, Thierry Daloze, Gilles Plourde, Pascal Meuret, Vincent Bonhomme2, Nadine Hajj-Ali, Steven B. Backman1, Alan C. Evans 
McGill University1, University of Liège2
01 Jul 1999-The Journal of Neuroscience
TL;DR: It is suggested that, at the concentrations attained, propofol preferentially decreases rCBF in brain regions previously implicated in the regulation of arousal, performance of associative functions, and autonomic control.
Abstract: In the present study, we used positron emission tomography to investigate changes in regional cerebral blood flow (rCBF) during a general anesthetic infusion set to produce a gradual transition from the awake state to unconsciousness. Five right-handed human volunteers participated in the study. They were given propofol with a computer-controlled infusion pump to achieve three stable levels of plasma concentrations corresponding to mild sedation, deep sedation, and unconsciousness, the latter defined as unresponsiveness to verbal commands. During awake baseline and each of the three levels of sedation, two scans were acquired after injection of an H215O bolus. Global as well as regional CBF were determined and correlated with propofol concentrations. In addition, blood flow changes in the thalamus were correlated with those of the entire scanned volume to determine areas of coordinated changes. In addition to a generalized decrease in global CBF, large regional decreases in CBF occurred bilaterally in the medial thalamus, the cuneus and precuneus, and the posterior cingulate, orbitofrontal, and right angular gyri. Furthermore, a significant covariation between the thalamic and midbrain blood flow changes was observed, suggesting a close functional relationship between the two structures. We suggest that, at the concentrations attained, propofol preferentially decreases rCBF in brain regions previously implicated in the regulation of arousal, performance of associative functions, and autonomic control. Our data support the hypothesis that anesthetics induce behavioral changes via a preferential, concentration-dependent effect on specific neuronal networks rather than through a nonspecific, generalized effect on the brain.

471 citations

"An obesity-associated risk allele w..." refers background in this paper

  • ...Decreased activity in the PCC is associated with low levels of arousal (Fiset et al., 1999)....

    [...]

Journal ArticleDOI
Body mass correlates inversely with inhibitory control in response to food among adolescent girls: an fMRI study.

[...]

Laura J. Batterink1, Sonja Yokum2, Eric Stice2
University of Oregon1, Oregon Research Institute2
01 Oct 2010-NeuroImage
TL;DR: Functional magnetic resonance imaging is used to investigate neural activations during a food-specific go/no-go task in adolescent girls ranging from lean to obese and suggests that hypofunctioning of inhibitory control regions and increased response of food reward regions are related to elevated weight.

469 citations

"An obesity-associated risk allele w..." refers background or result in this paper

  • ...…increasingly considered an addiction-type disorder with disruptions of the reward pathway, and several functional magnetic resonance imaging (fMRI) studies have explored this topic (Goldstone et al., 2009; Batterink et al., 2010; Gearhardt et al., 2011;Correspondence: Dr L. Wiemerslage, as above....

    [...]

  • ...And in line with our results, a previous fMRI study also showed reduced activation in the superior and middle frontal gyri as BMI increased (Batterink et al., 2010)....

    [...]

Journal ArticleDOI
Metabolism of phthalates in humans.

[...]

Hanne Frederiksen1, Niels E. Skakkebæk1, Anna-Maria Andersson1
Copenhagen University Hospital1
01 Jul 2007-Molecular Nutrition & Food Research
TL;DR: Exposure of the human foetus and infants to phthalates via maternal exposure is a matter of concern because of the differential distribution of the hydrophobic phthalate metabolites in breast milk compared to urine.
Abstract: Phthalates are synthetic compounds widely used as plasticisers, solvents and additives in many consumer products. Several animal studies have shown that some phthalates possess endocrine disrupting effects. Some of the effects of phthalates seen in rats are due to testosterone lowering effects on the foetal testis and they are similar to those seen in humans with testicular dysgenesis syndrome. Therefore, exposure of the human foetus and infants to phthalates via maternal exposure is a matter of concern. The metabolic pathways of phthalate metabolites excreted in human urine are partly known for some phthalates, but our knowledge about metabolic distribution in the body and other biological fluids, including breast milk, is limited. Compared to urine, human breast milk contains relatively more of the hydrophobic phthalates, such as di-n-butyl phthalate and the longer-branched, di(2-ethylhexyl) phthalate (DEHP) and di-iso-nonyl phthalate (DiNP); and their monoester metabolites. Urine, however, contains relatively more of the secondary metabolites of DEHP and DiNP, as well as the monoester phthalates of the more short-branched phthalates. This differential distribution is of special concern as, in particular, the hydrophobic phthalates and their metabolites are shown to have adverse effects following in utero and lactational exposures in animal studies.

465 citations

"An obesity-associated risk allele w..." refers background in this paper

  • ...Moreover, experiments in rodents show that changes in FTO expression levels in the hypothalamus affect feeding behaviour (Frederiksen et al., 2007; Olszewski et al., 2009; Tung et al., 2010)....

    [...]

Journal ArticleDOI
The obesity gene, FTO, is of ancient origin, up-regulated during food deprivation and expressed in neurons of feeding-related nuclei of the brain

[...]

Robert Fredriksson1, Maria Hägglund1, Pawel K. Olszewski, Olga Stephansson1, Josefin A. Jacobsson1, Agnieszka M. Olszewska1, Allen S. Levine, Jonas Lindblom1, Helgi B. Schiöth1 
Uppsala University1
01 May 2008-Endocrinology
TL;DR: The FTO gene is predominantly expressed in neurons, whereas it was virtually not found in astrocytes or glia cells, consistent with the hypothesis that FTO could participate in the central control of energy homeostasis.
Abstract: Gene variants of the FTO (fatso) gene have recently been strongly associated with body mass index and obesity. The FTO gene is well conserved and found in a single copy in vertebrate species including fish and chicken, suggesting that the ancestor of this gene was present 450 million years ago. Surprisingly, the FTO gene is present in two species of algae but not in any other invertebrate species. This could indicate that this gene has undergone a horizontal gene transfer. Quantitative real-time PCR showed that the gene is expressed in many peripheral and central rat tissues. Detailed in situ hybridization analysis in the mouse brain showed abundant expression in feeding-related nuclei of the brainstem and hypothalamus, such as the nucleus of the solitary tract, area postrema, and arcuate, paraventricular, and supraoptic nuclei as well as in the bed nucleus of the stria terminalis. Colabeling showed that the FTO gene is predominantly expressed in neurons, whereas it was virtually not found in astrocytes or glia cells. The FTO was significantly up-regulated (41%) in the hypothalamus of rats after 48-h food deprivation. We also found a strong negative correlation of the FTO expression level with the expression of orexigenic galanin-like peptide, which is mainly synthesized in the arcuate nucleus. These results are consistent with the hypothesis that FTO could participate in the central control of energy homeostasis.

357 citations

"An obesity-associated risk allele w..." refers result in this paper

  • ...BMI for the AA genotype was significantly higher than for the non-risk TT genotype (Student’s t-test, P < 0.05), as expected from previous reports (Fredriksson et al., 2008; S€allman Alm en et al., 2013)....

    [...]

  • ...05), as expected from previous reports (Fredriksson et al., 2008; S€allman Alm en et al., 2013)....

    [...]

Related Papers (5)
A link between FTO, ghrelin, and impaired brain food-cue responsivity

[...]

01 Aug 2013-Journal of Clinical Investigation
Efthimia Karra, Owen O'Daly, Agharul I. Choudhury, Ahmed Yousseif, Steven Millership, Marianne T. Neary, William R. Scott, Keval Chandarana, Sean Manning, Martin E. Hess, Hiroshi Iwakura, Takashi Akamizu, Queensta Millet, Cigdem Gelegen, Megan E. Drew, Sofia Rahman, Julian J. Emmanuel, Steven Williams, Ulrich Rüther, Jens C. Brüning, Dominic J. Withers, Fernando Zelaya, Rachel L. Batterham 
The fat mass and obesity associated gene (Fto) regulates activity of the dopaminergic midbrain circuitry

[...]

01 Aug 2013-Nature Neuroscience
Martin E. Hess, Simon Hess, Kate D. Meyer, Linda A W Verhagen, Linda Koch, Hella S. Brönneke, Marcelo O. Dietrich, Sabine D. Jordan, Yogesh Saletore, Olivier Elemento, Bengt F. Belgardt, Thomas Franz, Tamas L Horvath, Ulrich Rüther, Samie R. Jaffrey, Peter Kloppenburg, Jens C. Brüning 
A common variant in the FTO gene is associated with body mass index and predisposes to childhood and adult obesity

[...]

11 May 2007-Science
Timothy M. Frayling, Nicholas J. Timpson, Michael N. Weedon, Eleftheria Zeggini, Eleftheria Zeggini, Eleftheria Zeggini, Rachel M. Freathy, Cecilia M. Lindgren, John R. B. Perry, Katherine S. Elliott, Katherine S. Elliott, Hana Lango, Nigel W. Rayner, Nigel W. Rayner, Nigel W. Rayner, Beverley M. Shields, Lorna W. Harries, Jeffrey C. Barrett, Jeffrey C. Barrett, Sian Ellard, Christopher J. Groves, Christopher J. Groves, Bridget A. Knight, Ann-Marie Patch, Andy R Ness, Shah Ebrahim, Debbie A Lawlor, Susan M. Ring, Yoav Ben-Shlomo, Marjo-Riitta Järvelin, Marjo-Riitta Järvelin, Ulla Sovio, Ulla Sovio, Amanda J. Bennett, Amanda J. Bennett, David Melzer, Luigi Ferrucci, Ruth J. F. Loos, Inês Barroso, Nicholas J. Wareham, Fredrik Karpe, Fredrik Karpe, Katharine R. Owen, Katharine R. Owen, Lon R. Cardon, Mark Walker, Graham A. Hitman, Graham A. Hitman, Colin N. A. Palmer, Colin N. A. Palmer, Alex S. F. Doney, Alex S. F. Doney, Andrew D. Morris, George Davey Smith, Andrew T. Hattersley, Mark I. McCarthy 
An Obesity-Associated FTO Gene Variant and Increased Energy Intake in Children

[...]

11 Dec 2008-The New England Journal of Medicine
Joanne E. Cecil, Roger Tavendale, Peter Watt, Marion M. Hetherington, Colin N. A. Palmer 
FTO Obesity Variant Circuitry and Adipocyte Browning in Humans

[...]

02 Sep 2015-The New England Journal of Medicine
Melina Claussnitzer, Simon N. Dankel, Kyoung-Han Kim, Gerald Quon, Wouter Meuleman, Christine Haugen, Viktoria Glunk, Isabel S. Sousa, Jacqueline L. Beaudry, Vijitha Puviindran, Nezar Abdennur, Jannel Liu, Per-Arne Svensson, Yi-Hsiang Hsu, Daniel J. Drucker, Gunnar Mellgren, Chi-chung Hui, Hans Hauner, Manolis Kellis, Manolis Kellis 
Frequently Asked Questions (1)
Q1. What are the contributions in this paper?

56 To this end, the authors examined how an obesity risk-allele for the FTO gene affects brain activity in 57 response to food images of different caloric content via fMRI. Their results suggest that the two 66 genotypes are associated with differential neural processing of food images, which may 67 influence weight status through diminished impulse control and reward processing.