Phenotypic and genetic associations between anhedonia and brain structure in UK Biobank

Cullen, Breda; Lyall, Donald M.; Strawbridge, Rona J.; Smith, Daniel J.; Lyall, Laura

doi:10.1101/2020.06.29.20142984

Cited by 3 publications

(5 citation statements)

References 60 publications

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“…The pathways investigated here were previously found to be implicated in schizophrenia in both animal and human studies (4,17,53). In the current study, we were able to identify structural neuroimaging as well as clinical phenotypes associated with biologically informed PRSs, and these were shown to be more strongly associated with neuroimaging phenotypes than whole-genome PRS.…”

Section: Discussionmentioning

confidence: 88%

“…Here, the axon gene-set was associated with thalamic radiations, white matter microstructural tracts that link the thalamus to the rest of the cerebral cortex (50), and volume of the parahippocampal gyrus, a cortical region that plays a role in memory processes such as encoding and retrieval (51). Both neuroimaging phenotypes have been implicated in schizophrenia (52), and have recently been associated with state anhedonia and PRS for anhedonia, a core negative symptom of schizophrenia (53). The findings here indicate that genes conferring risk for schizophrenia that are aggregated in the axon gene-set are strengthening evidence for brain structural regions that are already implicated in schizophrenia psychopathology.…”

Section: Discussionmentioning

confidence: 99%

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Pathway-based polygenic risk scores for schizophrenia and associations with clinical and neuroimaging phenotypes in UK Biobank

Barbu

Thng

Adams

et al. 2022

Preprint

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Background: Schizophrenia is a heritable psychiatric disorder with a polygenic architecture. Genome-wide association studies (GWAS) have reported an increasing number of risk-associated variants and polygenic risk scores (PRS) now explain 17% of the variance in the disorder. There exists substantial heterogeneity in the effect of these variants and aggregating them based on biologically relevant functions may provide mechanistic insight into the disorder. Methods: Using the largest schizophrenia GWAS to date, we calculated PRS based on 5 pathways previously found to contribute to the pathophysiology of schizophrenia: the postsynaptic density, postsynaptic membrane, dendritic spine, axon, and histone H3-K4 methylation pathways. We associated each PRS, along with respective whole-genome PRS (excluding single nucleotide polymorphisms in each pathway), with neuroimaging (N>29,000; cortical, subcortical, and white matter microstructure) and clinical (N>119,000; psychotic-like experiences including conspiracies, communications, voices, visions, and distress) variables in healthy subjects in UK Biobank. Findings: A number of clinical and neuroimaging variables were significantly associated with the axon pathway (psychotic-like communications: β=0.0916, pFDR=0.04, parahippocampal gyrus volume: β=0.0156, pFDR=0.03, FA thalamic radiations: β=-0.014, pFDR=0.036, FA posterior thalamic radiations: β=-0.016, pFDR=0.048), postsynaptic density pathway (distress due to psychotic-like experiences: β=0.0588, pFDR=0.02, global surface area: β=-0.012, pFDR=0.034, and cingulate lobe surface area: β=-0.014, pFDR=0.04), and histone pathway (entorhinal surface area: β=-0.016, pFDR=0.035). In the associations above, whole-genome PRS were significantly associated with psychotic-like communications (β=0.2218, pFDR=1.34x10-7), distress (β=0.1943, pFDR=7.28x10-16), and FA thalamic radiations (β=-0.0143, pFDR=0.036). Permutation analysis carried out for these associations revealed that they were not due to chance. Discussion: Our results indicate that genetic variation in 3 pathways relevant to schizophrenia (axon, postsynaptic density, histone) may confer risk for the disorder through effects on a number of neuroimaging variables that have previously been implicated in schizophrenia. As neuroimaging associations were stronger for pathway PRS than whole-genome PRS, findings here highlight that selection of biologically relevant variants may address the heterogeneity of the disorder by providing further mechanistic insight into schizophrenia.

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Section: Discussionmentioning

confidence: 88%

Section: Discussionmentioning

confidence: 99%

Pathway-based polygenic risk scores for schizophrenia and associations with clinical and neuroimaging phenotypes in UK Biobank

Barbu

Thng

Adams

et al. 2022

Preprint

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“…The thalamus is involved in emotion regulation via limbic‐thalamo‐cortical projections (Ward, 2013), and previous research has reported positive correlations between optimism and left thalamic (Yang et al, 2013) and left nucleus accumbens volume in young adults (Dolcos et al, 2016). Similarly, anhedonia and lifetime major depressive disorder (MDD; negatively associated with wellbeing) are associated with smaller thalamus and nucleus accumbens volumes (Ancelin et al, 2019; Zhu et al, 2021). In terms of the caudate, a negative association between left caudate volume and subjective wellbeing ( n = 49, aged 12 years; Boyes et al, 2022) is supported by the current study.…”

Section: Discussionmentioning

confidence: 99%

“…One study found a positive association between subjective wellbeing-PGS and thickness of right superior temporal gyrus and volume of insula (n = 585; Song et al, 2019) while another found no evidence of wellbeing-PGS mediation on hippocampal volume (n = 636 twins/siblings; van't Ent et al, 2017). PGS of anhedonia was also associated with reduced total GMV and thickness of para-hippocampal, superior temporal gyrus and insula (n = 19,592;Zhu et al, 2021). Furthermore, imaging genetic studies have shown that brain structural variations are under polygenic influence (Grasby et al, 2020;Smith et al, 2021), but whether genetic variants that influence brain structure overlap with those that influence wellbeing is yet to be investigated.…”

Section: Introductionmentioning

confidence: 99%

Wellbeing and brain structure: A comprehensive phenotypic and genetic study of image‐derived phenotypes in the UK Biobank

Jamshidi

Park

Montalto

et al. 2022

Human Brain Mapping

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Wellbeing, an important component of mental health, is influenced by genetic and environmental factors. Previous association studies between brain structure and wellbeing have typically focused on volumetric measures and employed small cohorts. Using the UK Biobank Resource, we explored the relationships between wellbeing and brain morphometrics (volume, thickness and surface area) at both phenotypic and genetic levels. The sample comprised 38,982 participants with neuroimaging and wellbeing phenotype data, of which 19,234 had genotypes from which wellbeing polygenic scores (PGS) were calculated. We examined the association of wellbeing phenotype and PGS with all brain regions (including cortical, subcortical, brainstem and cerebellar regions) using multiple linear models, including (1) basic neuroimaging covariates and (2) additional demographic factors that may synergistically impact wellbeing and its neural correlates. Genetic correlations between genomic variants influencing wellbeing and brain structure were also investigated. Small but significant associations between wellbeing and volumes of several cerebellar structures (β = 0.015-0.029, P FDR = 0.007-3.8 Â 10 À9 ), brainstem, nucleus accumbens and caudate were found. Cortical associations with wellbeing included volume of right lateral occipital, thickness of bilateral lateral occipital and cuneus, and surface area of left superior parietal, supramarginal and pre-/post-central regions. Wellbeing-PGS was associated with cerebellar volumes and supramarginal surface area. Small mediation effects of wellbeing phenotype and PGS on right VIIIb cerebellum were evident. No genetic correlation was found between wellbeing and brain morphometric measures. We provide a comprehensive overview of wellbeing-related brain morphometric variation. Notably, small effect sizes reflect the multifaceted nature of this concept.

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“…There is very limited research into potential effects of rheumatoid arthritis (RA) on the brain. It is essential to investigate and monitor the role of cognition and brain phenotype differences that come with age as these can be a potentially early substrate of cognitive and psychological health Zhu et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

Associations between self-reported rheumatoid arthritis, rheumatoid factor positivity and structural brain phenotypes in the UK Biobank

Stanciu¹,

Lyall²,

Siebert³

et al. 2022

Preprint

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Objectives: The literature on structural brain health in people with rheumatoid arthritis (RA) is very limited. Our aim was to investigate whether there are any brain phenotype differences between people that are positive rheumatoid factor (RF+) and/or people that self-reported RA, compared with people who are not RF+ and do not report RA (‘healthy controls’). Methods: We tested for cross-sectional associations between RA and/or RF+ vs. several MRI brain volume variables in the UK Biobank (n=37, 379 participants, out of which 432 reported RA and 1,833 were RF+). We adjusted for age, sex, and assessment centre in the partially adjusted models, while in the fully adjusted models we additionally controlled for deprivation, smoking and cardiometabolic conditions. Results: Those that self-reported RA were more likely to have increased log white matter hyperintensity volumes (WMH standardised β= 0.08, 95% CI= 0.021; 0.14, p<0.01), and smaller volumes of the amygdala (β=-0.09, 95% CI= -0.16; -0.02, p<0.01) in the partially adjusted analyses. In the fully adjusted model RA remained significantly associated with amygdala volume (β=-0.09, 95% CI= -0.16; -0.02, p<0.01). No significant associations with RF+ status were found. Conclusion: Our study provides evidence for differences in structural brain volumes that are known to be related to psychological and cognitive health in those with vs. without RA. Since previous literature suggests a potential role for the amygdala in pain modulation and mental health, and an increased risk for stroke associated with WMH, we believe that our findings may be of clinical importance to people with RA. Further research is necessary to confirm these associations and asses their functional implications.

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Phenotypic and genetic associations between anhedonia and brain structure in UK Biobank

Cited by 3 publications

References 60 publications

Pathway-based polygenic risk scores for schizophrenia and associations with clinical and neuroimaging phenotypes in UK Biobank

Pathway-based polygenic risk scores for schizophrenia and associations with clinical and neuroimaging phenotypes in UK Biobank

Wellbeing and brain structure: A comprehensive phenotypic and genetic study of image‐derived phenotypes in the UK Biobank

Associations between self-reported rheumatoid arthritis, rheumatoid factor positivity and structural brain phenotypes in the UK Biobank

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