Genome-wide association studies (GWAS) have pinpointed genetic variations associated with various human traits, even complex ones influenced by multiple genes, such as height. But finding robust ties to intelligence has proven elusive. By harnessing the statistical power of data from nearly 80,000 people, scientists led by Danielle Posthuma at VU University Amsterdam have now added 40 new intelligence-linked genes to the current short list. The results appear in the May 22 issue of Nature Genetics. Among the traits that also associate with these new variants, Alzheimer’s emerged as the most negatively correlated.

Based on studies of families, particularly twins, researchers have known for decades that intelligence is highly heritable (Jansen et al., 2015). But nailing down which genes are responsible has been challenging. Measuring intellectual ability precisely and reliably is a problem, but more importantly, most genetic studies have been too small to accurately uncover the subtle effects of individual gene variants and probably identified false positives as well, researchers say (Chabris et al., 2012). 

Working in Posthuma’s lab, first author Suzanne Sniekers analyzed data from 78,308 individuals from 13 cohorts composed of children and adults of European descent. The sample included published GWAS results for intelligence on about 50,000 individuals (Benyamin et al., 2014; Davies et al., 2016). Sniekers correlated genetic variance with pooled data from a variety of IQ tests, most involving short, web-based quizzes taken remotely. “Luckily, there’s a high correlation between the results of the different tests, which we confirmed when we looked at the association data from each cohort independently,” said Posthuma.

Todd Lencz, from the Hofstra Northwell School of Medicine in Glen Oaks, New York, said he expected the short tests would be too crude. This is why his team stuck to the more rigorous tests in a recent study in which he identified two loci and seven genes associated with general cognitive function among 35,298 individuals (Trampush et al., 2017). “The proof is in the pudding, though,” said Lencz. “The short tests turned out to be robust enough.” 

To search for associations, Sniekers used standard GWAS, as well as a variant known as genome-wide gene association study (GWGAS), in which the effects of single-nucleotide polymorphisms (SNPs) within the same gene are combined to uncover hits that can be missed when the effects of individual SNPs fail to reach statistical significance. 

The researchers found three loci and 12 genes previously associated with cognition, plus they identified 15 new loci and 40 new genes. Many of the 52 genes are involved in neuronal function (including DCC, APBA1, PRR7, ZFHX3, HCRTR1, NEGR1, MEF2C, SHANK3, and ATXN2L), with several implicated in neuronal cell development. The strongest association was with FOXO3, a gene involved in insulin signaling. It has been linked to longevity (Willcox et al., 2008). In humans, FOXO3 and APOE are the only two genes whose association with lifespan has been widely replicated (Broer et al., 2015).

Despite the 40 new intelligence genes, the list is far from complete, researchers say. Lencz anticipates that hundreds, if not thousands, of additional variants exist. As GWAS studies get larger, more of these will be identified. “It’s like prospecting for gold, you keep searching and accumulating more in your bin,” he said.

To extend the reach of their study, Posthuma’s team compared their data to GWAS data for 32 other traits. Consistent with previous studies, they found education level was highly correlated with intelligence. They also found moderate, positive correlations with 13 other traits, including intracranial volume, head circumference in infancy, and success quitting smoking.

Peter Visscher, an expert in the genetics of complex traits at the University of Queensland in Brisbane, was unsurprised by the results. “The high genetic correlation with education attainment has been reported before (Okbay et al., 2016),” he wrote. Looking ahead, he considered that studies of education level will be critical for expanding our understanding of intelligence. “Sample size is king and it is much easier to get huge sample sizes for education,” he said. “It seems likely that in the near future there will be GWAS studies on education on millions of individuals, and such studies are likely to detect many hundreds of loci in the genome.” Posthuma is looking forward to the UK Biobank releasing data sets for 500,000 individuals, up from their current public collection of 100,000.

Although the study didn’t focus on Alzheimer’s, some curious connections emerged. FOXO3’s role in insulin signaling might be relevant given that several studies have linked insulin resistance to AD pathogenesis (for review see de la Monte, 2012; AlzRisk). Also, two of the 52 genes associated with intelligence, MEF2C and EXOC4, have been linked to synaptic function and AD.

Ekaterina Rogaeva of the University of Toronto previously pinpointed a region in the EXOC4 locus that associates with AD in Caribbean Hispanics, who have a higher incidence of AD than many other populations (Ghani et al., 2013). Rogaeva wondered if Posthuma’s results would replicate in non-Europeans. AD also surfaced as the trait most negatively correlated with intelligence. This ties in with the idea that people with a lot of cognitive reserve may escape frank dementia, even when they have underlying AD pathology. (See comment below.)

Can one conclude, then, that smart people are less likely to get AD? No, says Carlos Cruchaga at Washington University, Saint Louis. The overlap may shed light on common pathways, but what the correlations mean clinically is unclear. “There is more overlap in complex traits, including many neurological disorders, than we expected, but it’s too early to say how it all works,” said Cruchaga.—Marina Chicurel

Comments

  1. The investigation of genetic architecture of intelligence in such a large European data set is a very exciting topic. It is intriguing that among other significant findings, two loci (EXOC4 and MEF2C) were previously associated with Alzheimer’s disease. It would be important to see if some of the findings are replicated in the different ethnic groups. This is of note, because in our study of long runs of homozygosity in a Caribbean Hispanic cohort, a consensus region at the EXOC4 locus was significantly associated with Alzheimer’s disease (Ghani et al., 2013). EXOC4-intersecting runs of homozygosity might harbor variations influencing both risk for Alzheimer’s disease and intelligence.

    References:

    . Evidence of Recessive Alzheimer Disease Loci in a Caribbean Hispanic Data Set: Genome-wide Survey of Runs of Homozygosity. JAMA Neurol. 2013 Aug 26; PubMed.

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References

Paper Citations

  1. . What twin studies tell us about the heritability of brain development, morphology, and function: a review. Neuropsychol Rev. 2015 Mar;25(1):27-46. Epub 2015 Feb 12 PubMed.
  2. . Most reported genetic associations with general intelligence are probably false positives. Psychol Sci. 2012;23(11):1314-23. Epub 2012 Sep 24 PubMed.
  3. . Childhood intelligence is heritable, highly polygenic and associated with FNBP1L. Mol Psychiatry. 2014 Feb;19(2):253-8. Epub 2013 Jan 29 PubMed.
  4. . Genome-wide association study of cognitive functions and educational attainment in UK Biobank (N=112 151). Mol Psychiatry. 2016 Jun;21(6):758-67. Epub 2016 Apr 5 PubMed.
  5. . GWAS meta-analysis reveals novel loci and genetic correlates for general cognitive function: a report from the COGENT consortium. Mol Psychiatry. 2017 Mar;22(3):336-345. Epub 2017 Jan 17 PubMed.
  6. . FOXO3A genotype is strongly associated with human longevity. Proc Natl Acad Sci U S A. 2008 Sep 16;105(37):13987-92. Epub 2008 Sep 2 PubMed.
  7. . GWAS of longevity in CHARGE consortium confirms APOE and FOXO3 candidacy. J Gerontol A Biol Sci Med Sci. 2015 Jan;70(1):110-8. Epub 2014 Sep 8 PubMed.
  8. . Genome-wide association study identifies 74 loci associated with educational attainment. Nature. 2016 May 11;533(7604):539-42. PubMed.
  9. . Therapeutic targets of brain insulin resistance in sporadic Alzheimer's disease. Front Biosci (Elite Ed). 2012 Jan 1;4:1582-605. PubMed.
  10. . Evidence of Recessive Alzheimer Disease Loci in a Caribbean Hispanic Data Set: Genome-wide Survey of Runs of Homozygosity. JAMA Neurol. 2013 Aug 26; PubMed.

External Citations

  1. UK Biobank
  2. AlzRisk

Further Reading

No Available Further Reading

Primary Papers

  1. . Genome-wide association meta-analysis of 78,308 individuals identifies new loci and genes influencing human intelligence. Nat Genet. 2017 Jul;49(7):1107-1112. Epub 2017 May 22 PubMed.