Abstract
Glycated hemoglobin A1c (HbA1c) indicates the percentage of total hemoglobin that is bound by glucose, produced from the nonenzymatic chemical modification by glucose of hemoglobin molecules carried in erythrocytes. HbA1c represents a surrogate marker of average blood glucose concentration over the previous 8 to 12 weeks, or the average lifespan of the erythrocyte, and thus represents a more stable indicator of glycemic status compared with fasting glucose. HbA1c levels are genetically determined, with heritability of 47% to 59%. Over the past few years, inroads into understanding genetic predisposition by glycemic and nonglycemic factors have been achieved through genome-wide analyses. Here I review current research aimed at discovering genetic determinants of HbA1c levels, discussing insights into biologic factors influencing variability in the general and diabetic population, and across different ethnicities. Furthermore, I discuss briefly the relevance of findings for diabetes monitoring and diagnosis.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Introduction
Type 2 diabetes is a common metabolic disorder defined by the presence of markedly elevated levels of plasma glucose [1], which arise from dysregulations in the complex interplay between pancreatic β-cell function and insulin sensitivity in hepatic and skeletal muscle cells. Genetic association studies have recently revealed nearly 40 robustly replicated loci for type 2 diabetes [2]. Parallel, high-powered genome-wide analyses of quantitative glycemic traits [3–6, 7••] have provided alternative insights into the function of these loci, which are informing our understanding of disease pathophysiology.
Glycated hemoglobin A1c (HbA1c), or the percentage of total hemoglobin that is bound by glucose, provides a better estimate of average glycemia than routine determinations of blood glucose concentration, and is the most widely used index of chronic glycemia [8, 9]. It results from the nonenzymatic chemical modification of hemoglobin molecules carried in erythrocytes by glucose. The glycation process involves the nonenzymatic attachment of glucose to the NH-terminal N-terminal valine and internal lysine amino groups of hemoglobin [10]. The glycation reaction is mostly irreversible, so that the concentration of HbA1c is a function of the concentration of glucose to which the erythrocytes are exposed over their lifespan (120 days on average). HbA1c therefore represents a surrogate marker of average blood glucose concentration over the previous 8 to 12 weeks, thus representing a longer-term indicator of glycemic status compared with fasting glucose [11].
HbA1c levels are better predictors than fasting glucose of the development of long-term complications in type 1 and type 2 diabetes [12], and higher levels in the subdiabetic range have been shown to predict type 2 diabetes risk and cardiovascular disease [13, 14]. For these reasons an International Expert Committee has recently proposed a revision of the diagnostic criteria for diabetes, recommending that HbA1c may be a better means of diagnosing diabetes than measures of glucose (fasting and/or postchallenge) and that it be adopted as a diagnostic criterion for diabetes [15].
The heritability of HbA1c levels is relatively high (47% to 59%) when compared with fasting glucose (34% to 36%) or glucose level 2-hour post-oral glucose tolerance test (OGTT) (33%) [16, 17], and thus amenable to genetic analysis. Here I review current research aimed at discovering genetic determinants of HbA1c levels, discussing insights into biologic factors influencing variability in the general and diabetic population, and across different ethnicities. Furthermore, I discuss the relevance of findings for diabetes monitoring and diagnosis.
The First Generation of Genetic Studies: Linkage Scans and Candidate Gene Association Studies
There is a relative paucity of published reports on linkage and candidate gene association studies for HbA1c levels. The Framingham Heart Study conducted a genome-wide search for diabetes-related genes using measures of glycemia as quantitative traits (20-year mean fasting glucose, current fasting glucose, and HbA1c). A total of 771 men and women from 330 pedigrees from the 5th Offspring Study exam cycle (1991–1995) had information on HbA1c levels and were typed at 401 microsatellite markers (at an average spacing of 10 cM). Peak evidence for linkage to HbA1c levels was on the long arm of chromosome 1 at 187 cM (multipoint logarithm of the odds score, 2.81), in a model accounting for age, cigarette smoking, alcohol and estrogen use, physical activity, and body mass index. The same broad chromosomal region had been reported as having evidence for linkage for type 2 diabetes and quantitative fasting traits.
Among the first candidate gene studies, Shima et al. [18] tested the association of variants in the calpain-10 gene (CAPN10) gene—a candidate gene for type 2 diabetes originally reported in Mexican Americans—with several metabolic traits in 286 unselected Japanese subjects. They found one single nucleotide polymorphism (SNP-19) associated with higher body mass index and HbA1c levels at the nominal level under the dominant model (P = 0.003 and P = 0.024, respectively), indicating a contribution of CAPN10 variants to mild obesity and glucose intolerance in Japanese. More recently, Krízová et al. [19] tested associations of variants at two candidate genes of insulin resistance and type 2 diabetes mellitus, adiponectin (ADIPOQ) and resistin (RETN), in individuals of European ancestry. They genotyped SNPs 45T>G and 276G>T in ADIPOQ and 62G>A and −180C>G in RETN in patients with obesity, anorexia nervosa, and in control healthy normal-weight women, and tested associations with serum concentrations of these hormones and measures of insulin sensitivity and metabolic traits, including tumor necrosis factor-α, insulin, cholesterol, HbA1c, and blood glucose levels. They found significant associations of SNP ADP+276G>T allele with higher cholesterol levels in patients with anorexia, higher adiponectin concentrations in obese patients, and lower HbA1c levels in normal women. SNP of the resistin gene 62G>A was associated with lower HbA1c in normal women and higher cholesterol concentrations in the obese group. However, neither of these two associations at CAPN10 and RETN was replicated in further, high-powered genome-wide association studies (GWAS).
Locus Discovery through GWAS in Healthy Individuals
The advent of genome-wide SNP arrays and imputation-based meta-analysis has provided a robust statistical framework for discovery and replication, and boosted locus discovery revealing a wealth of genetic loci associated with disease and quantitative end points. GWAS of fasting glucose levels led to the identification of associations with HbA1c at three loci (G6PC2, MTNR1B, and GCK) [4, 5, 20–25]. The association of MTNR1B with HbA1c was furthermore replicated in 3210 unrelated Chinese Hans from Beijing [26], whereas to date no GWAS have been reported in non-European samples.
In the first GWAS of HbA1c levels, Paré et al. [27•] investigated 337,343 SNPs in 14,618 healthy women of European ancestry from the Women’s Genome Health Study, and validated their findings in 455 nondiabetic Caucasian participants recruited from the Boston metropolitan area. They detected four loci with significant association at the genome-wide level of 10−6. Of these, three were previously associated with type 2 diabetes or glycemic end points (GCK, SLC30A8, and G6PC2) [20, 21, 23, 25, 28] and in people free of diabetes. The fourth mapped to an intron in HK1, and was a novel locus.
Investigators of the MAGIC recently completed the largest to date meta-analysis of HbA1c levels [7••]. The genome-wide discovery set used in this study included approximately 2.5 million genotyped and imputed autosomal SNPs genotyped in 35,920 participants, a sample size that has 80% power to detect SNPs explaining 0.12% of the trait variance at the genome-wide significant threshold of P = 5 × 10−8. The analysis confirmed a strong statistical support at GCK, G6PC2/ABCB11, MTNR1B, and HK1, confirming previous reports [5, 21–25, 27•]. Furthermore, novel evidence for association was detected at six loci (in or near FN3K, HFE, TMPRSS6, ATP11A/TUBGCP3, ANK1, and SPTA1).
In parallel, Franklin et al. [29] completed a GWAS meta-analysis of glycated hemoglobin levels in 1782 healthy individuals from three genetically isolated populations: the Orkney Isles in the north of Scotland, the Dalmatian islands of Vis, and Korčula in Croatia. They reported a genome-wide significant association at an intronic variant in the TCF7L2 gene, the strongest common genetic risk factor for type 2 diabetes. An association at the same locus was also reported by Karns et al. [30] in a small sample of 843 individuals.
Associations with Correlated Metabolic and Hematologic Traits and Disease Provide Insights into Biologic Determinants of HbA1c Variance
In addition to ambient glycemia, it is known that medical conditions that change erythrocyte turnover, hereditary anemias, and iron storage disorders can influence the variability of HbA1c in populations [31]. The former include hemolytic anemias, chronic malaria, major blood loss, or blood transfusion; the latter are caused by rare causative mutations in genes involved in erythrocyte membrane stability, hemoglobin function, and glucose sensing and membrane transport in erythrocytes. It is thus of interest to assess if genetic variation segregating at high frequencies in the population, and causing subtler variation in these parameters, might also affect HbA1c. Furthermore, it is important to establish whether variation due to nonglycemic factors affects the utility of HbA1c in clinical practice.
Evidence from GWAS (Table 1) supports the notion that common variants might affect HbA1c levels through their effects on glucose levels and also through erythrocyte biology. A first evidence for this came from the study of Paré et al. [27•], who identified associations at four loci, including GCK, SLC30A8, G6PC2, and HK1. HK1 encodes the enzyme hexokinase, which catalyzed the first step in glycolysis and thus represents a likely candidate for the control of glucose metabolism. HK1 is the only isoform that is essential for red blood cell glucose metabolism [32], and is the predominant form among the four isozymes of the hexokinase family (HK1, HK2, HK3, and glucokinase). It is expressed in the vast majority of cells and tissues, including cells that are strictly dependent on glucose uptake for their metabolic needs [33]. In humans, rare nonsynonymous substitutions in the active site of HK1 and intragenic deletions have been shown to cause HK1 enzymatic deficiency associated with autosomal-recessive severe nonspherocytic hemolytic anemia [33–36]. The downeast anemia mice display HK1 deficiency and a similar anemic phenotype [32].
These observations led Bonnefond et al. [37•] to postulate that HK1 genetic variation may indirectly alter HbA1c measurements by generating a proanemic state, and independently of ambient blood glucose levels. They assessed the impact of the sentinel SNP at HK1 on HbA1c, glucose control-related traits (fasting- and 2-hour post-OGTT–related parameters), type 2 diabetes risk, and red blood cell–related parameters in Europeans. Surprisingly, the most associated SNP at this locus showed no association with any other markers of glucose control, whereas it was significantly associated with hemoglobin levels, hematocrit, and anemia.
The subsequent study by the MAGIC investigators [7••] provided additional evidence of HbA1c-associated loci with no evidence for association with glucose-control traits. Of the 10 loci associated with HbA1c at the genome-wide level, three had significant evidence for association of the HbA1c-raising allele with fasting glucose and β-cell function (GCK, MTNR1B, and G6PC2) in this and previous studies, and GCK also with 2-hour glucose [3–6, 24, 25, 27•, 38, 39]. Two of them (GCK and MTNR1B) were also associated with type 2 diabetes [3]. For the remaining seven we found no evidence for association with glycemic traits and diabetes, nor with insulin levels, despite adequate power. Of these, associations at the HFE and TMPRSS6 loci mapped to known functional variants in two complementary and directionally consistent pathways [40] and were associated with quantitative hematologic traits [7••, 41, 42]. At HFE the A allele at rs1800562 (Cys262Tyr), which is responsible for hereditary hemochromatosis (MIM 235200), was associated with lower levels of HbA1c, rather than the higher levels one would predict from epidemiologic observations of the increased HFE mutation prevalence in patients with type 2 diabetes [43, 44]. The reciprocal observation was seen for TMPRSS6, where the A allele at SNP rs855791 (Val736Ala) was associated with lower hemoglobin levels and higher HbA1c levels.
Three additional loci (SPTA1, ANK1, and including HK1 discussed earlier) showed suggestive associations with erythrocyte indexes, and rare variants at these loci cause hereditary anemias [45, 46]. We postulated that functional variants at HK1 may affect a potential dissociation between ambient plasma glucose and intracellular cytoplasmic glucose, and that the hemoglobin-lowering variant may affect the overall percent of HbA1c through an increased glucose/hemoglobin molar ratio, which in turn could increase the rate of hemoglobin that is glycated at a given glucose level. We further postulated a possible role of erythrocyte membrane stability and altered erythrocyte lifespan (ANK1, SPTA1) and hemoglobin deglycation (FN3K) based on the known function of the respective gene products mapping to the vicinity of the association signals.
These patterns were confirmed in analyses conditioned on fasting glucose or hematologic traits, which provided statistical support for an effect on HbA1c via regulation of systemic glucose concentrations for GCK, G6PC2, and MTNR1B, and via hematologic parameters for HFE, TMPRSS6, and HK1. Taken together, these results suggest that these common variants influence HbA1c levels via glycemic levels as well as erythrocyte physiology. Specific mechanisms are suggested by existing knowledge on the function of leading candidate genes in each region. These hypotheses will need to be tested to understand mechanistically and physiologically the effects of these genetic variants.
Discovery Studies in Individuals with Diabetes
The GWAS described before were all carried out in healthy individuals, using standardized analysis protocols and trait definition. The strength of this approach is that association results are not influenced by strong environmental confounders, principally disease status and antidiabetic medication. The observation that genetic associations underlying HbA1c levels at some loci are independent from fasting glucose reflects earlier observations in a classical discordant monozygotic (MZ) twin design by Snieder et al. [47]. Such analysis revealed a significant correlation in HbA1c levels in 45 MZ twins discordant for the disease (r = 0.52, P < 0.001; as opposed to r = 0.68, P < 0.001 in 33 MZ twins concordant for diabetes), suggesting that a substantial proportion of heritability was due to diabetes-independent familial effects. Although robust estimates of the proportion of phenotypic variance attributable to diabetes-independent genetic effects are still lacking, these results showed for the first time that familial factors might explain variation in HbA1c levels that is not dependent on glycemic control.
Recently, Paterson et al. [48•] carried out a genome-wide analysis on repeated measures of HbA1c from the DCCT with the aim to identify genetic loci underlying glycemic control in individuals with type 1 diabetes. The study sample consisted of two sets of individuals sampled from the conventional (n = 667) and intensive (n = 637) treatment groups of the DCCT. Genome-wide SNPs were tested for association with mean HbA1c, stratified by intervention arm as well as in the combined cohort. This analysis yielded a large number of SNPs (233) significant at the set threshold of P = 10−4, indicating an excess of false-positive owing to relatively underpowered study samples. Successive steps were used to prioritize loci for replication, assessing the association of these loci with capillary glucose and repeated measures of multiple complications of diabetes. For replication, associations were assessed through a series of (non-independent) analyses testing associations with quarterly HbA1c using repeated measures, with mean daily glucose and baseline C-peptide (to confirm a glycemic mechanism), with HbA1c repeated measures in the combined cohort (adjusting for treatment group and testing for interaction with treatment), and with glycemic complications including coronary calcium, neuropathy, hypoglycemia, and time to renal or retinal complications (in each arm separately).
Loci having evidence for association after these steps, including SNPs near SORCS1 at 10q25.1, GSC at 14q32.13, BNC2 at 9p22, and WDR72 at 15q21.3, were carried forward for replication in two independent replication samples. These included the GoKinD study, a case–control collection of patients with type 1 diabetes with and without diabetic nephropathy, and healthy subjects from the MAGIC meta-analysis described earlier. These analyses revealed a locus (rs1358030 near SORCS1) where association reached the widely accepted threshold for genome-wide significance of P < 5 × 10−8 in the conventional treatment group, which was also associated with mean glucose and showed suggestive evidence for replication in the intensive treatment group and in the control group in GoKinD. However, this association was not seen among GoKinD participants with nephropathy nor in the MAGIC sample. Another signal near BNC2 showed suggestive evidence in MAGIC but did not replicate in GoKinD. SNPs in both regions were associated with diabetes complications in the expected direction: SORCS1 with hypoglycemia (and less robustly with both retinopathy and nephropathy) and BNC2 with microvascular end points.
It remains to be established if these variable replication outcomes stem from limited study power, or reflect the variable effect of the environment—most notably insulin treatment—in the two study arms of the study. We direct the readers to an accompanying editorial to the study [49] for a more detailed exploration of these effects. A recent study explored the same four loci BNC2, SORCS1, GSC, and WDR72 for their effect on glycemic control in type 2 diabetes [50]. The authors typed 1486 subjects with type 2 diabetes from a Norwegian population-based cohort (HUNT2), and tested their effects on HbA1c and non-fasting glucose levels individually and in a combined genetic score model. They detected no significant associations with HbA1c or glucose and partially inconsistent direction of associations. Further studies in other populations are needed to identify whether genetic variants affect glycemic control in type 1 and type 2 diabetes.
Impact of Genetic Discoveries on the Use of HbA1c in Diabetes Monitoring, Diagnosis, and Treatment in Europeans
Recently, an International Expert Committee has proposed a revision of the diagnostic criteria for diabetes, recommending that HbA1c may be a better means of diagnosing diabetes than measures of glucose (fasting and/or postchallenge) and that it be adopted as a diagnostic criterion for diabetes [51]. The 2010 American Diabetes Association Standards of Medical Care in Diabetes added the HbA1c ≥48 mmol/L (≥6.5%) as another criterion for the diagnosis of diabetes [52]. The recommendation is based on the association of microvascular complications with HbA1c being at least as strong as those with fasting or postchallenge glucose, that HbA1c is subject to less day-to-day variability than fasting or postchallenge glucose, and that it can be measured at any time of the day without preparations such as fasting or a glucose challenge. It is likely that practical, medical, methodologic, and financial factors will prevent implementation of the recommendation in the majority of clinical settings. It is nevertheless important to understand how genetic factors underlying normal variation in HbA1c through nonglycemic routes might influence diabetes diagnosis.
In addition to severe pathologies characterized by altered erythrocyte physiology (e.g., inherited hemoglobinopathies) that may influence the utility of HbA1c in diabetes diagnosis [31, 51, 53, 54], we and others showed that genetically determined physiologic variation in the general population can also play a role, affecting HbA1c levels through subtler but more widespread alterations of iron levels and/or hemoglobin concentration. We sought to quantify these genetic effects in population-level terms, and to evaluate the resulting risk of misclassifying individuals as diabetic or nondiabetic owing to genetic influences on HbA1c. Using net reclassification analysis, we estimated that the population-level impact of the seven nonglycemic loci when HbA1c ≥6.5% is used as the reference cutoff for diabetes diagnosis was approximately 2% (P = 0.002). This estimate represents an upper boundary for the effect of these common variants, as most people (the majority in the center of the distribution) are expected to have a smaller individual genotype effect size. This suggests that variation in HbA1c levels due to common, nonglycemic effect variants might influence only minimally diagnosis or misclassification of diabetes.
Interethnic Differences in the Allelic Architecture of HbA1c Levels and Their Impact on Diabetes Diagnosis
HbA1c values are higher in African Americans than in the population of European ancestry. Furthermore, variants at loci controlling iron metabolism associated with HbA1c levels are known to vary across ethnic groups. For instance, the A allele frequency at rs1800562 (HFE) is absent in populations of West African and East Asian ancestry (www.hapmap.org) but is relatively common (~5%) in Europe. The T allele at rs855791 (TMPRSS6) is at approximately 39% in Europeans, but relatively rare in West African (~11%) and East Asian (~5%) populations. These observations raise the question of how variation in frequency and effect size in diverse populations may affect reclassification of diabetes status by HbA1c.
Although the effect of individual loci has not been explored, Maruthur et al. [55•] explored the contribution of inherited interethnic differences in HbA1c levels in a cross-sectional analysis of 2294 individuals of African American ancestry from the community-based ARIC study. As rates of admixture with Europeans vary among African Americans, the percentage of European genetic ancestry for each individual, estimated from ancestry-informative markers, was compared with HbA1c levels categorized using American Diabetes Association diagnostic cut points (<5.7, 5.7–6.4, and ≥6.5%). This analysis showed that HbA1c levels were positively correlated to the fraction of the genome that was of European origin (P < 0.001), although this correlation accounted for a minimal fraction (<1%) of the overall variability. Compared with genetic ancestry, socioeconomic, demographic, and metabolic risk factors were estimated to play a considerably greater role in governing changes in HbA1c. As previously discussed for Europeans, these results suggest that the inherited variability among populations is likely to have a negligible impact on HbA1c-based diabetes classification, and that the relative contribution of demographic and metabolic factors far outweighs the contribution of genetic ancestry to HbA1c values in African Americans.
Conclusions and Outlook
Current evidence suggests that high-powered genetic analyses provide important new opportunities for dissecting genetic influences of HbA1c levels. These initiatives will be important not only to better understand genetic and biologic determinants of HbA1c variation in the general population, but also to inform recent initiatives to focus diabetes diagnosis and care more centrally on HbA1c. It will be of considerable interest in the future to explore additional areas of study.
First, as more variants are discovered through sequencing and fine-mapping efforts, it will be important to reassess genetic predisposition and reclassification rates in European and non-European populations. Second, it will be important to extend the study of genetic influences to HbA1c in prediabetic and diabetic populations, although the confounding effects of treatment might obscure any role of these polymorphisms in the diabetic population. Finally, additional genetic associations may be revealed from studies of low-to-intermediate frequency variants through imputation from the 1000 Genomes Project, direct association using whole-genome sequencing data, and in-depth replication and locus fine-mapping through custom arrays. These hypothesis-generating genetic efforts will pave the way for further studies of the role of the new loci in hemoglobin glycation, glucose metabolism, and diabetes.
Abbreviations
- ARIC:
-
Atherosclerosis Risk in Communities
- DCCT:
-
Diabetes Control and Complications Trial
- GoKinD:
-
Genetics of Kidneys in Diabetes
- MAGIC:
-
Meta-Analyses of Glucose and Insulin Related Traits Consortium
References
Papers of particular interest, published recently, have been highlighted as: • Of importance •• Of major importance
Group AC, Patel A, MacMahon S, Chalmers J, Neal B, Billot L, et al. Intensive blood glucose control and vascular outcomes in patients with type 2 diabetes. In N Engl J Med. 2008;358:2560–72.
Voight BF, Scott LJ, Steinthorsdottir V, Morris AP, Dina C, Welch RP, et al. Twelve type 2 diabetes susceptibility loci identified through large-scale association analysis. In Nat Genet. 2010;42:579–89.
Dupuis J, Langenberg C, Prokopenko I, Saxena R, Soranzo N, Jackson AU, et al. New genetic loci implicated in fasting glucose homeostasis and their impact on type 2 diabetes risk. Nat Genet. 2010;42:105–16.
Lyssenko V, Nagorny CL, Erdos MR, Wierup N, Jonsson A, Spegel P, et al. Common variant in MTNR1B associated with increased risk of type 2 diabetes and impaired early insulin secretion. Nat Genet. 2009;41:82–8.
Prokopenko I, Langenberg C, Florez JC, Saxena R, Soranzo N, Thorleifsson G, et al. Variants in MTNR1B influence fasting glucose levels. Nat Genet. 2009;41:77–81.
Saxena R, Hivert MF, Langenberg C, Tanaka T, Pankow JS, Vollenweider P, et al. Genetic variation in GIPR influences the glucose and insulin responses to an oral glucose challenge. Nat Genet. 2010;42:142–8.
•• Soranzo N, Sanna S, Wheeler E, Gieger C, Radke D, Dupuis J, Bouatia-Naji N, Langenberg C, Prokopenko I, Stolerman E, et al. Common variants at 10 genomic loci influence hemoglobin A1C levels via glycemic and nonglycemic pathways. Diabetes. 2010;59:3229–39. This is the largest GWAS of HbA 1c published to date.
Singer DE, Coley CM, Samet JH, Nathan DM. Tests of glycemia in diabetes mellitus. Their use in establishing a diagnosis and in treatment. Ann Intern Med. 1989;110:125–37.
Nathan DM, Singer DE, Hurxthal K, Goodson JD. The clinical information value of the glycosylated hemoglobin assay. New Engl J Med. 1984;310:341–6.
Bunn HF. Nonenzymatic glycosylation of protein: relevance to diabetes. In Am J Med. 1981;70:325–30.
Mortensen HB, Christophersen C. Glucosylation of human haemoglobin a in red blood cells studied in vitro. Kinetics of the formation and dissociation of haemoglobin A1c. Clin Chim Acta. 1983;134:317–26.
Intensive blood-glucose control with sulphonylureas or insulin compared with conventional treatment and risk of complications in patients with type 2 diabetes (UKPDS 33). UK Prospective Diabetes Study (UKPDS) Group. In Lancet, Volume 352; 1998. p. 837–53.
Pradhan AD, Rifai N, Buring JE, Ridker PM. Hemoglobin A1c predicts diabetes but not cardiovascular disease in nondiabetic women. Am J Med. 2007;120:720–7.
Khaw K-T, Wareham N. Glycated hemoglobin as a marker of cardiovascular risk. In Curr Opin Lipidol. 2006;17:637–43.
Frayling TM. Genome-wide association studies provide new insights into type 2 diabetes aetiology. In Nat Rev Genet. 2007;8:657–62.
Meigs JB, Panhuysen CI, Myers RH, Wilson PW, Cupples LA. A genome-wide scan for loci linked to plasma levels of glucose and HbA(1c) in a community-based sample of Caucasian pedigrees: the Framingham Offspring Study. Diabetes. 2002;51:833–40.
Pilia G, Chen WM, Scuteri A, Orru M, Albai G, Dei M, et al. Heritability of cardiovascular and personality traits in 6,148 Sardinians. PLoS Genet. 2006;2:e132.
Shima Y, Nakanishi K, Odawara M, Kobayashi T, Ohta H. Association of the SNP-19 genotype 22 in the calpain-10 gene with elevated body mass index and hemoglobin A1c levels in Japanese. Clin Chim Acta. 2003;336:89–96.
Krízová J, Dolinková M, Lacinová Z, Sulek S, Dolezalová R, Housová J, et al. Adiponectin and resistin gene polymorphisms in patients with anorexia nervosa and obesity and its influence on metabolic phenotype. Physiol Res. 2008;57:539–46.
Weedon M, Clark V, Qian Y, Ben-Shlomo Y, Timpson N, Ebrahim S, et al. A common haplotype of the glucokinase gene alters fasting glucose and birth weight: association in six studies and population-genetics analyses. In Am J Hum Genet. 2006;79:991–1001.
Sparso T, Andersen G, Nielsen T, Burgdorf K, Gjesing A, Nielsen A, et al. The GCKR rs780094 polymorphism is associated with elevated fasting serum triacylglycerol, reduced fasting and OGTT-related insulinaemia, and reduced risk of type 2 diabetes. In Diabetologia. 2008;51:70–5.
Orho-Melander M, Melander O, Guiducci C, Perez-Martinez P, Corella D, Roos C, et al. Common missense variant in the glucokinase regulatory protein gene is associated with increased plasma triglyceride and C-reactive protein but lower fasting glucose concentrations. Diabetes. 2008;57:3112–21.
Chen W, Erdos M, Jackson A, Saxena R, Sanna S, Silver K, et al. Variations in the G6PC2/ABCB11 genomic region are associated with fasting glucose levels. In J Clin Invest. 2008;118:2620–8.
Bouatia-Naji N, Bonnefond A, Cavalcanti-Proenca C, Sparso T, Holmkvist J, Marchand M, et al. A variant near MTNR1B is associated with increased fasting plasma glucose levels and type 2 diabetes risk. Nat Genet. 2009;41:89–94.
Bouatia-Naji N, Rocheleau G, Van Lommel L, Lemaire K, Schuit F, Cavalcanti-Proenca C, et al. A polymorphism within the G6PC2 gene is associated with fasting plasma glucose levels. In Science. 2008;320:1085–8.
Liu C, Wu Y, Li H, Qi Q, Langenberg C, Loos RJF, et al. MTNR1B rs10830963 is associated with fasting plasma glucose, HbA1C and impaired beta-cell function in Chinese Hans from Shanghai. BMC Med Genet. 2010;11:59.
• Paré G, Chasman DI, Parker AN, Nathan DM, Miletich JP, Zee RY, Ridker PM. Novel association of HK1 with glycated hemoglobin in a non-diabetic population: a genome-wide evaluation of 14,618 participants in the Women’s Genome Health Study. PLoS Genet. 2008;4:e1000312. This is the first GWAS for HbA 1c.
Weedon MN, Frayling TM, Shields B, Knight B, Turner T, Metcalf BS, et al. Genetic regulation of birth weight and fasting glucose by a common polymorphism in the islet cell promoter of the glucokinase gene. Diabetes. 2005;54:576–81.
Franklin CS, Aulchenko YS, Huffman JE, Vitart V, Hayward C, Polašek O, et al. The TCF7L2 diabetes risk variant is associated with HbA1C levels: a genome-wide association meta-analysis. Ann Hum Genet. 2010;74:471–8.
Karns R, Zhang G, Jeran N, Havas-Augustin D, Missoni S, Niu W, et al. Replication of genetic variants from genome-wide association studies with metabolic traits in an island population of the Adriatic coast of Croatia. Eur J Hum Genet. 2011;19:341–6.
Roberts W, Safar-Pour S, De B, Rohlfing C, Weykamp C, Little R. Effects of hemoglobin C and S traits on glycohemoglobin measurements by 11 methods. In Clin Chem. 2005;51:776–8.
Peters LL, Lane PW, Andersen SG, Gwynn B, Barker JE, Beutler E. Downeast anemia (dea), a new mouse model of severe nonspherocytic hemolytic anemia caused by hexokinase (HK(1)) deficiency. In Blood Cell Mol Dis. 2001;27:850–60.
van Wijk R, van Solinge WW. The energy-less red blood cell is lost: erythrocyte enzyme abnormalities of glycolysis. In Blood. 2005;106:4034–42.
van Wijk R, Rijksen G, Huizinga EG, Nieuwenhuis HK, van Solinge WW. HK Utrecht: missense mutation in the active site of human hexokinase associated with hexokinase deficiency and severe nonspherocytic hemolytic anemia. In Blood. 2003;101:345–7.
McMullin MF. The molecular basis of disorders of red cell enzymes. In J Clin Pathol. 1999;52:241–4.
Kanno H, Murakami K, Hariyama Y, Ishikawa K, Miwa S, Fujii H. Homozygous intragenic deletion of type I hexokinase gene causes lethal hemolytic anemia of the affected fetus. In Blood. 2002;100:1930.
•• Bonnefond A, Vaxillaire M, Labrune Y, Lecoeur C, Chevre J-C, Bouatia-Naji N, Cauchi S, Balkau B, Marre M, Tichet J, et al. Genetic variant in HK1 -is associated with a proanemic state and A1C but not other glycemic control-related traits. Diabetes. 2009;58:2687–97. This study introduced the concept that genetic variants affecting HbA 1c may do so by influencing nonglycemic mechanisms.
Weedon MN, Clark VJ, Qian Y, Ben-Shlomo Y, Timpson N, Ebrahim S, et al. A common haplotype of the glucokinase gene alters fasting glucose and birth weight: association in six studies and population-genetics analyses. Am J Hum Genet. 2006;79:991–1001.
Chen WM, Erdos MR, Jackson AU, Saxena R, Sanna S, Silver KD, et al. Variations in the G6PC2/ABCB11 genomic region are associated with fasting glucose levels. J Clin Investig. 2008;118:2620–8.
Schmidt PJ, Toran PT, Giannetti AM, Bjorkman PJ, Andrews NC. The transferrin receptor modulates Hfe-dependent regulation of hepcidin expression. Cell Metabol. 2008;7:205–14.
Ganesh SK, Zakai NA, van Rooij FJ, Soranzo N, Smith AV, Nalls MA, et al. Multiple loci influence erythrocyte phenotypes in the CHARGE consortium. Nat Genet. 2009;41:1191–8.
Soranzo N, Spector TD, Mangino M, Kuhnel B, Rendon A, Teumer A, et al. A genome-wide meta-analysis identifies 22 loci associated with eight hematological parameters in the HaemGen consortium. Nat Genet. 2009;41:1182–90.
Conte D, Manachino D, Colli A, Guala A, Aimo G, Andreoletti M, et al. Prevalence of genetic hemochromatosis in a cohort of Italian patients with diabetes mellitus. Ann Intern Med. 1998;128:370–3.
Phelps G, Chapman I, Hall P, Braund W, Mackinnon M. Prevalence of genetic haemochromatosis among diabetic patients. Lancet. 1989;2:233–4.
Rijksen G, Akkerman JW, van den Wall Bake AW, Hofstede DP, Staal GE. Generalized hexokinase deficiency in the blood cells of a patient with nonspherocytic hemolytic anemia. Blood. 1983;61:12–8.
Bianchi M, Magnani M. Hexokinase mutations that produce nonspherocytic hemolytic anemia. Blood Cell Mol Dis. 1995;21:2–8.
Snieder H, Sawtell PA, Ross L, Walker J, Spector TD, Leslie RD. HbA(1c) levels are genetically determined even in type 1 diabetes: evidence from healthy and diabetic twins. In Diabetes. 2001;50:2858–63.
• Paterson AD, Waggott D, Boright AP, Hosseini SM, Shen E, Sylvestre M-P, Wong I, Bharaj B, Cleary PA, Lachin JM, et al. A genome-wide association study identifies a novel major locus for glycemic control in type 1 diabetes, as measured by both A1C and glucose. Diabetes. 2010;59:539–49. This is a GWAS for HbA 1c in the context of antidiabetic treatment (as opposed to those conducted in nondiabetic populations).
Florez JC. A genome-wide association study of treated A1C: a genetic needle in an environmental haystack? Diabetes. 2010;59:332–4.
Hertel JK, Johansson S, Ræder H, Platou CG, Midthjell K, Hveem K, et al. Evaluation of four novel genetic variants affecting hemoglobin A1c levels in a population-based type 2 diabetes cohort (the HUNT2 study). BMC Med Genet. 2011;12:20.
International expert committee report on the role of the A1C assay in the diagnosis of diabetes. Diabetes Care. 2009;32:1327–34.
Executive summary: standards of medical care in diabetes—2010. Diabetes Care. 2010;33 Suppl 1:S4–10.
Panzer S, Kronik G, Lechner K, Bettelheim P, Neumann E, Dudczak R. Glycosylated hemoglobins (GHb): an index of red cell survival. Blood. 1982;59:1348–50.
Cohen RM, Franco RS, Khera PK, Smith EP, Lindsell CJ, Ciraolo PJ, et al. Red cell life span heterogeneity in hematologically normal people is sufficient to alter HbA1c. Blood. 2008;112:4284–91.
• Maruthur NM, Kao WH, Clark JM, Brancati FL, Cheng CY, Pankow JS, Selvin E. Does genetic ancestry explain higher values of glycated hemoglobin in African Americans? Diabetes. 2011;60:2434–8. This is a recent study suggesting that genetic variation explains a relatively small proportion of the differences in HbA 1c across populations.
Disclosure
No potential conflict of interest relevant to this article was reported.
Open Access
This article is distributed under the terms of the Creative Commons Attribution Noncommercial License which permits any noncommercial use, distribution, and reproduction in any medium, provided the original author(s) and source are credited.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
Open Access This is an open access article distributed under the terms of the Creative Commons Attribution Noncommercial License (https://creativecommons.org/licenses/by-nc/2.0), which permits any noncommercial use, distribution, and reproduction in any medium, provided the original author(s) and source are credited.
About this article
Cite this article
Soranzo, N. Genetic Determinants of Variability in Glycated Hemoglobin (HbA1c) in Humans: Review of Recent Progress and Prospects for Use in Diabetes Care. Curr Diab Rep 11, 562–569 (2011). https://doi.org/10.1007/s11892-011-0232-9
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11892-011-0232-9