Skip to main content

Genes Shape Personality Traits

How Genes Shape Personality Traits: New Links Are Discovered



Your DNA has long been known to play a role in shaping your personality. Now, researchers at Yale School of Medicine (YSM) have taken another step in determining exactly how by identifying a number of new genetic sites associated with specific personality traits. They published their findings in Nature Human Behavior on August 12.

Using data from the Million Veteran Program, researchers performed a genome-wide association study (GWAS) to identify genetic variations, called “loci,” associated with each of the “Big Five” personality traits: extraversion, openness, agreeableness, neuroticism, and conscientiousness. The researchers then combined these data with previous GWAS to perform a meta-analysis with almost 700,000 individuals, marking the largest GWAS for personality traits to date.

“We are a step closer in that process of increasing the sample size to be able to more clearly understand which variants are truly related to these personality traits,” says Daniel Levey, PhD, assistant professor of psychiatry at YSM and principal investigator of the study.

The Big Five and novel loci

The Big Five personality traits are a scientifically based measure of personality that can be studied using self-reported assessments that indicate whether people score high or low in each of the five traits. Participants in the Million Veteran Program, a national research program that collects data including genetic information from veterans to better understand genes and health, completed these assessments in addition to providing a blood sample for genetic analysis.

By comparing personality assessment results with the analysis of variations in the participants’ DNA, Levey and his team found 62 new loci associated with neuroticism. They also identified loci for agreeableness for the first time. By combining their results with previously published data, they performed a meta-analysis to identify over 200 genetic loci across the five personality traits.

Even with the large number of genetic variations they found, Levey hopes that they will be able to further expand on these studies in the future, eventually increasing the number of participants to millions of people rather than hundreds of thousands and increasing the diversity of participants as well. Current studies of genes and personality have been largely made up of people with European ancestry.

“To be able to be confident in saying what direction of effect these variations have and what the actual precise effect of the variation is, we need to have vastly larger sample sizes,” Levey says. “Current human genetic studies are homogenous relative to the world populations. If you were able to bring in more diverse people and you were able to look at how associations in one population versus another overlap, it would give us a tighter definition.”

Genes, personality, and mental health

Levey and his team also investigated genetic correlations between personality traits and various mental health conditions. They found that there was a strong overlap between neuroticism, a personality trait marked by negative feelings, and depression and anxiety. People with high agreeableness, a personality trait marked by a tendency to get along well with others, were less likely to experience these conditions. These associations are already well understood from a psychiatric perspective, but Levey’s findings provide additional genetic confirmation.

Priya Gupta, PhD, postdoctoral associate in Levey’s lab and first author of the manuscript, says that “although genetics are largely beyond our control, gaining a deeper understanding of our personality traits can help us become more aware of potential mental health risks and develop effective coping strategies to address these risks.”

But just because there is a genetic basis for the associations between personality traits and certain mental health conditions, it doesn’t mean that those associations last a lifetime, Levey says.

“Your personality will adapt and change over time, so there’s a temporal relationship which we’re not necessarily capturing with the cross-sectional way we’re looking at personality in our study,” he says. “Just because we’re finding these genetic variations doesn’t mean that these are things that are fated that you can’t change about your life.”

Levey hopes that personality studies such as these might one day be useful in informing early treatment for mental health conditions.

“When you’re looking at these personality traits that are more predisposed to later developing mental illness, that could be a prodromal [a period of subclinical symptoms] look at who might be at higher risk, and then maybe it might be grounds for intervention,” he says. “Even if we can measure genetically the associations to traits like neuroticism, that doesn’t mean that you can’t alter your strategies for dealing with life in ways that could help you achieve better outcomes.”

genetic testing, consumer genomics, direct-to-consumer testing, DNA sequencing, personalized medicine, genetic counseling, ancestry testing, carrier screening, pharmacogenomics, hereditary disease risk, whole-genome sequencing, molecular diagnostics, genotyping technologies, health genomics, predictive analytics, clinical genomics, genome editing, bioinformatics tools, nutrigenomics, polygenic risk scores

#GeneticTesting, #ConsumerGenomics, #DNATesting, #PersonalizedMedicine, #GeneticCounseling, #AncestryTesting, #CarrierScreening, #Pharmacogenomics, #HereditaryRisk, #GenomeSequencing, #MolecularDiagnostics, #HealthGenomics, #PredictiveMedicine, #ClinicalGenomics, #Genotyping, #GenomeEditing, #Bioinformatics, #Nutrigenomics, #GenomicsMarket, #PolygenicRiskScores

Comments

Popular posts from this blog

Fruitful innovation

Fruitful innovation: Transforming watermelon genetics with advanced base editors The development of new adenine base editors (ABE) and adenine-to-thymine/ guanine base editors (AKBE) is transforming watermelon genetic engineering. These innovative tools enable precise A:T-to-G and A:T-to-T base substitutions, allowing for targeted genetic modifications. The research highlights the efficiency of these editors in generating specific mutations, such as a flowerless phenotype in ClFT (Y84H) mutant plants. This advancement not only enhances the understanding of gene function but also significantly improves molecular breeding, paving the way for more efficient watermelon crop improvement. Traditional breeding methods for watermelon often face challenges in achieving desired genetic traits efficiently and accurately. While CRISPR/Cas9 has provided a powerful tool for genome editing, its precision and scope are sometimes limited. These limitations highlight the need for more advanced gene-e...

Genetic factors with clinical trial stoppage

Genetic factors associated with reasons for clinical trial stoppage Many drug discovery projects are started but few progress fully through clinical trials to approval. Previous work has shown that human genetics support for the therapeutic hypothesis increases the chance of trial progression. Here, we applied natural language processing to classify the free-text reasons for 28,561 clinical trials that stopped before their endpoints were met. We then evaluated these classes in light of the underlying evidence for the therapeutic hypothesis and target properties. We found that trials are more likely to stop because of a lack of efficacy in the absence of strong genetic evidence from human populations or genetically modified animal models. Furthermore, certain trials are more likely to stop for safety reasons if the drug target gene is highly constrained in human populations and if the gene is broadly expressed across tissues. These results support the growing use of human genetics to ...

Genetic Test

Genetic test eliminates progressive retinal atrophy in English shepherd dogs Researchers at the University of Cambridge recently published their findings in Genes after identifying the genetic mutation that is causing progressive retinal atrophy (PRA) in English shepherd dogs. PRA is a group of inherited diseases causing progressive degeneration of the light sensitive cells within the back of the eyes. When it comes to PRA in dogs, they are born with normal vision but by the age of 4-5 they go totally blind with no treatment. According to the release, by identifying the canines carrying this disease before they lose vision, this can be then used as a tool to guide breeding decisions to prevent the passing of the disease onto puppies.1 Historically, owners did not realize their dog had PRA until they were middle-aged, which means it could have been passed on to puppies if they had bred, making this a hard disease to control. “Once the dog’s eyesight starts to fail there’s no treatment ...