Identification of novel high-impact recessively inherited type 2 diabetes risk variants in the Greenlandic population

Numerous genome-wide association studies (GWAS) have been performed to identify genetic factors predisposing to type 2 diabetes. These studies, mainly performed in European and Asian populations, have identified around 120 genetic variants associated with risk of type 2 diabetes [1‐8].

Until now, GWAS of type 2 diabetes and glycaemic traits have almost exclusively been performed using an additive genetic model [1‐5]. This model, however, has limited statistical power to detect associations with variants displaying recessive effects [9, 10], unless the effect is very large. Recently, a GWAS of type 2 diabetes in up to 4040 individuals with type 2 diabetes and 116,246 participants without diabetes from the UK Biobank applied a dominance deviation model to identify non-additive association signals [11]. Although no novel signals were identified, the paper reported a recessive effect on risk of type 2 diabetes at the previously identified CDKAL1 locus [11], which is in concordance with the findings from the original discovery [12]. Importantly, given the effective sample size of around 15,300, this study lacked statistical power to exclude the possibility that additional alleles with recessive effects predispose to type 2 diabetes in European populations.

We previously demonstrated the existence of a high-impact type 2 diabetes risk allele with predominately recessive effect in the Greenlandic population, despite using an additive genetic model in the discovery analysis [13]. Notably, however, this TBC1D4 loss-of-function variant was discovered via analyses of a type 2 diabetes-related trait, 2 h plasma glucose, on which it had an extremely large effect, and not via analyses of type 2 diabetes. Indeed, the study in which that variant was discovered had very limited statistical power to detect variants with recessive effects on type 2 diabetes unless they were very frequent and had very large effects. Here, we aimed to identify additional variants with recessive effects on risk of type 2 diabetes in the Greenlandic population by applying a recessive genetic model to an increased number of Greenlandic samples with type 2 diabetes information.

We analysed association with type 2 diabetes for 317 individuals with type 2 diabetes and 2631 participants with normal glucose tolerance. Using a recessive genetic model on these Greenlandic data, we identified three loci associated with type 2 diabetes below the study-wide Bonferroni-corrected significance threshold (p < 4.3 × 10⁻⁷) (ESM Fig. 1). Besides the previously described TBC1D4 locus [13], these comprised two novel loci, namely the common intron variant rs870992 in ITGA1 on chromosome 5 (MAF 23%, OR 2.79, p = 1.8 × 10⁻⁸) and the common intergenic variant rs16993330 approximately 25 kb upstream of LARGE1 on chromosome 22 (MAF 16%, OR 3.52, p = 1.3 × 10⁻⁷) (Fig. 1, Table 1). However, the LARGE1 variant did not reach the conventional threshold for genome-wide significance (p < 5 × 10⁻⁸). Similar associations with type 2 diabetes were observed when adjusting for BMI (data not shown).

The Greenlandic population is admixed with ancestry from both Inuit and Europeans [30]. Interestingly, the estimated EAF were considerably higher in the Inuit ancestry component for ITGA1 rs870992 (31%) and for LARGE1 rs16993330 (19%), than in the European ancestry component among Greenlanders (3% and 7%, respectively) and in European populations (Table 1, ESM Table 2). The allele frequencies found in Europeans were so low that homozygous carriers were almost absent. The novel variants in ITGA1 and LARGE1 had a high impact on risk of type 2 diabetes in Greenlanders, evident by the estimated effect sizes (Table 1) and by the higher frequency of type 2 diabetes among homozygous carriers compared with non-carriers (24.9% and 28.9% vs 10%; Fig. 2). To gain further insights into the effect of the identified loci, we also performed type 2 diabetes association analyses of these assuming an additive model (Table 1). This led to low p values as well, although none of them was low enough to pass the Bonferroni-corrected significance threshold (p < 4.3 × 10⁻⁷). Based on genetic data and functional annotation analyses facilitated by in silico tools, we were unable to determine whether the identified variants were causal.

Next, to elucidate the diabetes-related mechanisms underlying the association of the novel variants, we analysed diabetes-related traits in individuals without diabetes from the Greenlandic cohorts with a recessive genetic model. Homozygous carriers of ITGA1 rs870992 had nominally increased HbA_1c levels (β = 0.13 SD [95% CI 0.027, 0.23], p = 0.012) (Table 2). For LARGE1 rs16993330, the underlying physiological mechanism seems to be linked to increased fat accumulation, indicated by higher levels of visceral adipose tissue (0.29 SD [95% CI 0.076, 0.50], p = 0.0078), larger hip circumference (0.22 SD [95% CI 0.048, 0.40], p = 0.013) and waist circumference (0.21 SD [95% CI 0.041, 0.38], p = 0.015) and higher BMI (0.18 SD [95% CI 0.0046, 0.35], p = 0.045) (Table 2). Furthermore, homozygous LARGE1 rs16993330 carriers had increased insulin resistance, indicated by higher levels of fasting serum insulin (0.22 SD [95% CI 0.027, 0.41], p = 0.026) and HOMA-IR (0.24 SD [95% CI 0.048, 0.44], p = 0.014), and lower levels of the ISI (−0.21 SD [95% CI −0.016, −0.41], p = 0.034) (Table 2). We then performed the analyses of the same quantitative diabetes-related traits with an additive model and obtained similar results (ESM Table 3).

We subsequently attempted to validate our findings in another Arctic indigenous population by genotyping the ITGA1 and LARGE1 variants in 1059 Alaska Native Yup’ik. However, none of the potential associations with diabetes-related quantitative traits were replicated in this smaller sample (ESM Table 4), and analysis of type 2 diabetes was precluded due to the low number of participants with diabetes. A second line of replication was attempted in a Danish sample of 5220 individuals with type 2 diabetes and 18,556 control participants. However, we did not observe an association with type 2 diabetes using a recessive model (ESM Table 2). In addition, the results of a dominance deviance model GWAS of European UK Biobank samples [11] showed no significant rejection of the additive model for either ITGA1 rs870992 or LARGE1 rs16993330 (p = 0.54 and p = 0.36, respectively) based on 117,775 individuals. We also queried the two variants from the available summary data from a recent additive genetic model GWAS of type 2 diabetes [8] and found that the ITGA1 rs870992 G allele was nominally associated with increased risk of type 2 diabetes, whereas no effect was observed for LARGE1 rs16993330 (ESM Table 5). Additionally, queries of results from GWAS of other traits revealed associations of the ITGA1 rs870992 G allele with increased total cholesterol and LDL-cholesterol levels, and nominal associations of the LARGE1 rs16993330 A allele with increased total cholesterol and triacylglycerol levels (ESM Table 5). Owing to the possible inflation of the test statistics, we also included the quantile of p values for the significant tests in ESM Table 5.

Finally, we queried RNA expression data available online as part of the GTEx project (www.​gtexportal.​org/) under the hypothesis that the newly identified variants in ITGA1 and LARGE1 could change the expression of regional genes. Here we observed that the type 2 diabetes-associated ITGA1 rs870992 G allele was associated with increased ITGA1 RNA expression in nerve, pancreas and smooth muscle tissue in up to 361 samples, albeit with modest p values (p < 0.0001). No expression quantitative trait loci (eQTL) associations were found for LARGE1 rs16993330.

Using a recessive genetic model, we investigated the association between markers on MetaboChip and type 2 diabetes in a Greenlandic study population. Besides the established TBC1D4 locus [13], we identified a novel genome-wide significant variant for risk of type 2 diabetes in ITGA1, and a variant near LARGE1 showing a suggestive association. Additional analyses of diabetes-related quantitative traits indicated that the LARGE1 variant might increase the risk of type 2 diabetes through accumulation of visceral fat and increased insulin resistance, whereas these analyses provided no clues to the mechanistic link underlying the ITGA1 association. This study demonstrates the value of using the correct genetic model for identification of disease-associated variants, which is also supported by simulations showing that, for example, for a recessive effect allele with a frequency of 0.25 and an OR of 3 (similar to the ITGA1 variant), the power under an additive model is less than 20% whereas the power under a recessive model is around 80% (ESM Fig. 2). Moreover, under a wide range of EAF and ORs, the recessive model has markedly higher statistical power to detect variants with recessive effects associated with type 2 diabetes.

A possible link between the ITGA1 locus and altered glucose regulation is supported by studies of type 2 diabetes-related traits. Recently, rs6450057 mapping to PELO, a gene embedded in intron 1 of ITGA1, was found to be associated with fasting serum insulin levels in a transethnic GWAS meta-analysis of 70,000 individuals [40]. Interestingly, this study found an opposite direction of effect in European and African-American samples, indicating that rs6450057 is not the causal variant at this locus. Moreover, another ITGA1 intron variant, rs6867040, has been associated with fasting plasma glucose concentrations in 46,262 European individuals [41], and a recent prepublished GWAS of more than 800,000 samples showed an independent association between three variants at the ITGA1 locus and type 2 diabetes using an additive genetic model [42]. These studies support our findings of a link between variation in ITGA1 and type 2 diabetes. However, it is unclear whether it is the same signal, as the identified variants in the European study do not include rs870992, nor are the identified variants in high linkage disequilibrium with rs870992 in Europeans (r² < 0.1).

Biologically, ITGA1 is an attractive candidate gene, encoding the α1-integrin subunit, which heterodimerises with the β1 subunit to form cell surface receptors that bind collagen and laminin. Interestingly, α1β1-integrin is the primary collagen receptor used by cultured beta cells, and this interaction regulates beta cell adhesion, motility and insulin secretion [43, 44]. Moreover, specific interactions between α1β1-integrin and extracellular matrix have been shown to be critical for beta cell survival and function [45], and therefore are possibly also important for glucose homeostasis and risk of type 2 diabetes. Besides the possible effects on beta cell function, ITGA1 seems to be linked to liver function. Thus, ITGA1 variants have been associated with plasma levels of the liver enzyme γ-glutamyl transferase [46], and modestly with ITGA1 protein expression levels in the liver [41]. In mice, knocking out Itga1 leads to severe hepatic insulin resistance [47] and altered fatty acid metabolism when they are fed a high-fat diet [48]. In line with this, we observed a borderline significant association between ITGA1 rs870992 and increased levels of fasting plasma glucose, which might indicate altered hepatic glucose regulation in the fasted state. Thus, studies of phenotypes reflecting liver function in Greenlanders would be of great interest to elucidate the biological mechanisms underlying the association between variation in ITGA1 and type 2 diabetes. In eQTL analyses, no effect of the type 2 diabetes-associated rs870992 variant on mRNA expression in liver tissue was observed. Instead, the variant was associated with increased ITGA1 expression in three other tissues; however, this was in the opposite direction to what was expected from the Itga1 knockout mice. This difference might rely on the fact that rs870992 is unlikely to be the causal variant and therefore we cannot conclude that the causal variant acts through RNA regulation even if our top SNP is significantly associated with ITGA1 expression.

No previous studies have indicated a link between LARGE1 and type 2 diabetes in additive model GWAS [8], nor did we replicate our findings in recessive analysis in a Danish sample of 5220 individuals with diabetes and 18,556 control participants. This lack of association in European samples may rely on low statistical power for recessive effects, due to the low frequency of risk alleles (EAF<10%) in Europeans (ESM Fig. 2) or due to population-specific differences in linkage disequilibrium between the identified variant and the causal variant. It is also possible that the causal variant behind the observed type 2 diabetes association is Inuit-specific, similar to the risk variant in TBC1D4 [13]. However, we were unable to pinpoint such a causal variant. Moreover, the lack of replication of the diabetes-related quantitative traits associations in a small sample of Alaska Native Yup’ik illustrates one of the main challenges with studies of isolated populations, namely the difficulty of finding appropriate replication cohorts in terms of both genetic composition and sample size. It is, however, also possible that the LARGE1 association represents a false-positive discovery.

LARGE1 encodes the LARGE xylosyl- and glucuronyltransferase 1 protein. This protein interacts with α-dystroglycan and functions as a glycosyltransferase stimulating glycosylation of α-dystroglycan, which in skeletal muscles connects the cytoplasm with the extracellular matrix as part of the dystrophin–glycoprotein complex [49, 50]. How this relates to the observed association with visceral fat accumulation and insulin resistance is unclear; therefore studies including a more comprehensive coverage of the genome and a larger sample size are warranted to verify the suggested associations, and possibly identify the causal variant in the locus.

In this study, we observed three loci, TBC1D4, ITGA1 and LARGE1, harbouring variants with large recessive effects on the risk of type 2 diabetes in Greenlanders, the latter, however, having weaker statistical support. In addition to these loci, based on a loss-of-function screening of the same population, we recently identified a variant in ADCY3 recessively associated with obesity and type 2 diabetes [51]. Variants in all four loci have effect sizes that are much greater than what has been reported for TCF7L2, which is the greatest genetic risk factor for type 2 diabetes among Europeans [1]. Even though the estimated effects are likely to be inflated by the ‘winner’s curse’, these variants have the potential to be of clinical relevance by facilitating the prediction of diabetes development in Greenlandic population. More research is needed to identify the causal variants, to elucidate the biological mechanisms underlying the association with type 2 diabetes, and to clarify whether these novel variants distinguish type 2 diabetes subtypes with specific aetiology, as demonstrated for TBC1D4 [13]. This additional knowledge could have the potential to guide choice of treatment for subtypes of type 2 diabetes.

In conclusion, we demonstrate that common alleles with recessive effects play a role in the genetic architecture of type 2 diabetes in the small and historically isolated Greenlandic population. These findings reiterate the importance of considering non-additive genetic models when performing GWAS.