Methods  This was a multicenter study based on 518 subjects with long-standing diabetes mellitus (DM), 173 with type 1 DM (T1DM) and 345 with type 2 DM (T2DM). Study groups consisted of 233 control subjects with no DR, 155 subjects with nonproliferative DR, 126 with proliferative DR, and 90 with clinically significant macular edema. Subjects with end-stage renal disease were excluded. DNA extracted from blood of each subject was genotyped for 3 EPO single-nucleotide polymorphisms (SNPs).

Results  All 3 SNPs in EPO were associated with overall DR status in the combined T1DM and T2DM and T2DM alone groups (CC genotype of rs507392, P < .008; GG genotype of rs1617640, P < .008; and CC genotype of rs551238, P < .008) in the multivariate analysis. The GCC haplotype was also associated with overall DR status in the combined DM and T2DM alone groups (P = .008) by multivariate analysis. All SNPs and the GCC haplotype were also associated with proliferative DR and clinically significant macular edema in the combined DM and T2DM alone groups. No associations were found with T1DM alone.

Conclusion  Sequence variation in EPO is associated with the risk of DR independent of duration of DM, degree of glycemic control, and nephropathy.

Clinical Relevance  Identifying EPO genetic markers for high risk of developing DR could lead to the possibility of developing novel treatments or preventive therapies.

EPO is a glycoprotein that plays a major role in stimulation of bone marrow stem cells and erythropoiesis. It has also been shown to stimulate proliferation, migration, and angiogenesis in vascular endothelial cells exposed to hypoxia.^3-4 EPO messenger RNA is expressed in the human retina.^5-6 Expression of EPO receptors in vascular endothelial cells⁷ and the retina^{6, 8} has also been demonstrated. Many studies have reported a higher concentration of EPO in the vitreous of patients with DM and proliferative DR (PDR) when compared with controls.^{5, 9-11} Animal studies have shown increased EPO concentrations in ischemic retinas^12-13 and EPO inhibitors preventing neovascularization, further supporting the role of EPO in the development of PDR.¹³

EPO expression is influenced by single-nucleotide polymorphisms (SNPs) in EPO.¹² Interestingly, there is no correlation between the vitreous and plasma levels of EPO, suggesting increased vitreous EPO is due to increased local production of EPO in the retina^{9, 14} rather than due to increased systemic EPO production by the kidney.

The human EPO gene is located on chromosome 7q21.¹⁵ Recently, Tong et al¹² genotyped 613 subjects with type 2 DM (T2DM) (374 with PDR and end-stage renal disease [ESRD] and 239 controls with complication-free DM) for 19 SNPs in 11 genes involved in angiogenesis, including EPO. The only significant association with DR was found at SNP rs1617640 in the promoter of EPO, where the T allele was significantly associated with PDR and ESRD (P = .00191). This finding was replicated in 2 type 1 DM (T1DM) cohorts (1244 with PDR with or without ESRD and 715 controls with complication-free DM) with all subjects being European American (overall P = 2.76x10^–11). The TTA haplotype of SNPs rs1617640, rs507392, and rs551238 were also disease associated (P = .0005).¹² We aimed to determine whether the same EPO sequence variation was associated with DR development in Australian subjects with DM and without ESRD.

METHODS

Retinopathy status was obtained from the treating ophthalmologist and graded according to the Early Treatment Diabetic Retinopathy Study criteria.¹⁶ Blinding DR was defined as severe nonproliferative DR, PDR, or clinically significant macular edema (CSME). A detailed questionnaire containing information regarding ethnicity, age at diagnosis, family DM history, coexisting risk factors, systemic complications of DM, ocular complications as a result of DR, ocular history, smoking history, and alcohol intake was conducted. Blood pressure and body mass index were measured. Renal function tests (serum creatinine and urine albumin levels and albumin:creatinine ratio) and blood cholesterol and hemoglobin A_1c (HbA_1c) levels were obtained. Three recent HbA_1c levels were averaged for each participant. For those cases diagnosed with blinding DR, HbA_1c levels at the time of diagnosis of the ocular complication were used, and for controls with noncomplicated DM, HbA_1c levels immediately prior to recruitment were used. Patients were classified as having hypertension if they were receiving treatment for hypertension or they had a blood pressure reading greater than or equal to 140/90 mm Hg at the time of recruitment. Hypercholesterolemia was defined as a total cholesterol level greater than 212 mg/dL (to convert to millimoles per liter, multiply by 0.0259) or current use of lipid-lowering medication. Nephropathy was defined as the presence of microalbuminuria (albumin level, 0.03-0.3 g per day) or macroalbuminuria (albumin level, >0.3 g per day) but not meeting ESRD criteria.

DNA was extracted from peripheral blood samples using the QiaAmp Blood Maxi Kit (Qiagen, Valencia, California). The same 3 EPO SNPs reported in Tong et al¹² (rs1617640, rs507392, and rs551238) were genotyped in all individuals using the Sequenom iPLEX Gold chemistry (Sequenom, San Diego, California) on an Autoflex mass spectrometer (Sequenom, Brisbane, Australia) at the Australia Genome Research Facility, Brisbane. Three individuals for each genotype at each SNP were sequenced to confirm the integrity of the genotyping assay. Single-nucleotide polymorphism genotyping was checked for compliance with Hardy-Weinberg equilibrium (HWE) using a ² test. Linkage disequilibrium between markers and allelic association tests were calculated in Haploview 4.0 (http://www.broadinstitute.org/mpg/haploview). Genotypic associations were assessed in SNPStats.¹⁷ Dominant and recessive models were considered with respect to the minor allele. Odds ratios were calculated in SPSS (version 15.0; SPSS Inc, Chicago, Illinois). Haplotypic associations were undertaken in Haplo Stats (version 1.2.1)¹⁸ in 1 block of linkage disequilibrium.

RESULTS

Subjects with T1DM and no DR had a significantly lower age, shorter disease duration, lower cholesterol level, and less hypertension when compared with subjects with T1DM and DR. Subjects with T2DM and no DR were more likely to be female and have shorter disease duration, lower HbA_1c level, and higher BMI when compared with subjects with T2DM and DR (Table 1).

View this table: [in this window] [in a new window] [as a PowerPoint slide]   Table 1. Clinical Characteristics of Participants With No DR Compared With DR Cases in T1DM and T2DM

All 3 SNPs were in strong linkage disequilibrium (D' = 1.0, r² = 1.0 for all comparisons) and were in HWE when assessed in the total cohort (P > .05). When broken down by type of DM and DR status, participants with T2DM and no DR deviated from HWE (P = .009) for all 3 SNPs. Genotype frequencies of all SNPs in both DM subgroups are shown in Table 2. Given the strong linkage disequilibrium observed, all 3 SNPs gave identical association results. All 3 SNPs in EPO were associated with DR status in the combined DM group (T1DM and T2DM) and T2DM alone. The GG genotype of rs1617640, CC genotype of rs507392, and CC genotype of rs551238 were all significantly associated with the presence of DR after adjustment for age, sex, HbA_1c level, duration of disease, and nephropathy in the combined DM group (P = .008, data not shown). In the subanalysis for type of DM, these genotypes were significantly associated with DR in the T2DM group (P = .006) (Table 3) but not the T1DM group, although the total number of subjects with T1DM was fewer, reducing the statistical power to detect an association in this group. In the multivariate analyses, further subclassification for the type of DR found all 3 SNPs to be associated with PDR, CSME, and blinding DR in the combined DM group (P = .030, P = .040, and P = .033, respectively) and T2DM alone (P = .020, P = .018, and P = .016, respectively). In addition to controlling for age, sex, HbA_1c level, duration of disease, and nephropathy, further multivariate analyses were undertaken, also controlling for hypertension, hypercholesterolemia, BMI, and smoking. All 3 SNPs continued to be significantly associated with overall DR, PDR, and blinding DR in the combined DM group and T2DM alone (P < .05, data not shown). No associations were found in an allelic association model for any SNP and DR (or its subtypes) in the combined DM group or T1DM or T2DM alone (P > .05, data not shown).

View this table: [in this window] [in a new window] [as a PowerPoint slide]   Table 2. Genotype Frequencies for Each SNP in Participants With No DR and DR Cases by Type of Diabetes Mellitus

View this table: [in this window] [in a new window] [as a PowerPoint slide]   Table 3. P Values for Association of EPO SNPs With DR in T1DM and T2DM

The GCC haplotype was found at a higher frequency in the combined DM and T2DM alone groups with DR than the control group. This association was significant under a recessive model after adjusting for sex, HbA_1c level, duration of disease, and nephropathy (P = .008) (Table 4). This haplotype was also associated with PDR, CSME, and blinding DR in the combined DM group (P = .030, P = .040, and P = .008, respectively) and T2DM alone (P = .027, P = .031, and P = .009, respectively). No significant association was observed for T1DM alone.

View this table: [in this window] [in a new window] [as a PowerPoint slide]   Table 4. Association of Haplotypes With Blinding DR in T1DM and T2DMa

COMMENT

This study found an association between 3 EPO SNPs and DR in a cohort of subjects with DM, with the GCC haplotype having an increased frequency in patients with T2DM with DR. In contrast to our study, Tong et al¹² identified the T allele of rs1617640 to be the risk-associated allele with PDR. It was also reported that the same allele in the EPO promoter region had a major effect on EPO messenger RNA transcription levels in an in vitro model. The opposite haplotype (TAA) was reported as the risk allele for PDR in their study.¹² Similar overall allele frequencies (across combined cases and controls) were observed in the 2 studies. However, a major and important difference between the 2 cohorts is the complete lack of ESRD in the current study, compared with the majority of cases having ESRD in the Tong et al study. As opposed to Tong et al, this study did not find an association of the EPO SNPs with DR in T1DM. The substantially larger T1DM cohort of Tong et al had additional power, which may explain the lack of association observed in the current study.

End-stage renal disease leads to anemia through reduced EPO production. Although similar vascular processes may be involved in the pathogenesis of both diabetic nephropathy and DR, it is possible that different genetic factors play a role in their susceptibility. The development of DR^19-25 and nephropathy^26-31 have each been shown to have a strong genetic component. However, the majority of the chromosomes believed to be involved in the inheritance of nephropathy and retinopathy susceptibility are not shared.^{19, 24-25,29, 31} It is therefore possible that different variations within EPO play a role in DR and ESRD development and therefore possible that Tong et al have identified variations in EPO responsible only for ESRD, accounting for the differences between our and their findings. Previous studies have also suggested no association of plasma EPO levels with increased vitreous EPO, but rather increased vitreous levels to be due to local production of EPO in the retina.^9-10 Further studies investigating factors influencing local and systemic production of EPO and tissue-specific effects of EPO gene regulation are also required to further understand the role of EPO in DR and ESRD pathogenesis.

This study is not the first to report an opposite allele/genotype of the same SNP to be associated with a disease. For example, the G and C allele of SNP rs3741916 of the glyceraldehyde-3-phosphate dehydrogenase gene have been reported by different studies to be significantly associated with Alzheimer disease in white subjects.^32-33 This "flip flop" phenomenon may occur when a single locus association is found in the presence of multilocus effects and this single locus association may be confounded by other loci. Another reason can include sampling variation among the studies, whereby the magnitude of an association between an allele and risk of disease varies across different (especially ethnic) populations because of the presence of different linkage disequilibrium patterns. Finally, associations of opposite alleles of the same SNP may occur because of differences in its relationship with other causal variants, including environmental factors.³⁴

Another important consideration is the deviation from HWE observed in the T2DM no DR group. This group was as highly selected as the controls, and thus, the deviation is not unexpected in the presence of a true association. However, there is a chance that this deviation is due to population stratification. The T1DM groups conformed to HWE as did the T2DM with DR group, indicating that recruitment bias and genotyping errors are likely not the cause. However, the reported association does depend on the group that does not conform to HWE.

Subjects with no DR in our study had shorter duration of DM and fewer associated vasculopathic risk factors when compared with those with DR. We accept this as a limitation of our study; however, an attempt to overcome these influences on the outcome of results has been made by adjusting for these factors in the multivariate analyses.

In conclusion, our results show that in an Australian white population, variation in EPO predicts the risk of developing DR, independent of duration of DM. There is clearly a need for further independent association studies to further explore the role of EPO sequence variation in DR susceptibility. Also, further functional characterization is required to better elucidate the role of EPO in DR and ESRD development. If confirmed, this finding leads to the possibility of developing treatments or preventive therapies for DR based on a clearer understanding of the mechanism of involvement of EPO in DR development.

AUTHOR INFORMATION

Submitted for Publication: February 9, 2009; final revision received July 7, 2009; accepted July 18, 2009.

Author Contributions: Assoc Prof Craig had full access to all the data in the study and takes responsibility for the integrity of the data and the accuracy of the data analysis.

Financial Disclosure: None reported.

Funding/Support: The Ophthalmic Research Institute of Australia and the Flinders Medical Research Foundation provided financial assistance for the conductance of the study and collection of the data. This research was supported by a grant from the Ophthalmic Research Institute of Australia. Dr Burdon is a Peter Doherty Fellow of the National Health and Medical Research Council of Australia and Assoc Prof Craig is a National Health and Medical Research Council of Australia Practitioner Fellow.

Additional Contributions: We thank our participating patients and their ophthalmologists, research nurses, and laboratory assistants.

This article was corrected online for typographical errors on 1/11/2010.

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