Role of telomeres and associated maintenance genes in Type 2 Diabetes Mellitus: A review

Accepted Manuscript Review Role of Telomeres and Associated Maintenance Genes in Type 2 Diabetes Mellitus: A Review Itty Sethi, G.R. Bhat, Vinod Singh, Rakesh Kumar, A.J.S. Bhanwer, Rameshwar N. K. Bamezai, Swarkar Sharma, Ekta Rai PII: DOI: Reference:

S0168-8227(16)30800-2 http://dx.doi.org/10.1016/j.diabres.2016.10.015 DIAB 6779

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Diabetes Research and Clinical Practice

Received Date: Revised Date: Accepted Date:

23 February 2016 9 October 2016 16 October 2016

Please cite this article as: I. Sethi, G.R. Bhat, V. Singh, R. Kumar, A.J.S. Bhanwer, R.N. K. Bamezai, S. Sharma, E. Rai, Role of Telomeres and Associated Maintenance Genes in Type 2 Diabetes Mellitus: A Review, Diabetes Research and Clinical Practice (2016), doi: http://dx.doi.org/10.1016/j.diabres.2016.10.015

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Role of Telomeres and Associated Maintenance Genes in Type 2 Diabetes Mellitus: A Review Itty Sethia, G.R. Bhata, Vinod Singha, Rakesh Kumara, AJS Bhanwerb, Rameshwar N. K. Bamezaic, Swarkar Sharmaa, Ekta Raia Affiliations: a

Human Genetics Research Group, Department of Biotechnology, Shri Mata Vaishno Devi University Katra, J&K, 182320. b Department of Human Genetics, Guru Nanak Dev University, Amritsar, 143005, Punjab, India. c National Centre of Applied Human Genetics, School of Life Sciences, Jawaharlal Nehru University, New Delhi 110067. Corresponding Authors: Dr. Swarkar Sharma, Ph.D. Human Genetics Research Group, Department of Biotechnology Shri Mata Vaishno Devi University, Katra, Jammu and Kashmir, 182320 Tel: 01991-285535 // 285524 // 285634 // 285699 extn: 2533 Email: [email protected] Dr. Ekta Rai Human Genetics Research Group, Department of Biotechnology Shri Mata Vaishno Devi University, Katra, Jammu and Kashmir, 182320 Tel: 01991-285535 // 285524 // 285634 // 285699 extn: 2533 Email: [email protected]

Abstract Type 2 Diabetes Mellitus (T2DM), a multifactorial complex disorder, is coming up as a major cause of morbidity, mortality and socio-economic burden across the world. Despite huge efforts in understanding genetics of T2DM, only ~10% of the genetic factors have been identified so far. Telomere attrition, a natural phenomenon, reported to be exacerbated in cases of T2DM, and has recently emerged in understanding the pathophysiology of T2DM. It has been indicated that Telomeres and associated pathways might be the critical components in the disease etiology, though the mechanism(s) involved are not clear. Recent Genome Wide (GWAS) and Candidate Gene Case-Control Association Studies have also indicated an association of Telomere and associated pathways related genes with T2DM. Single Nucleotide Polymorphisms (SNPs) in the telomere maintenance genes: TERT, TERC, TNKS, CSNK2A2, TEP1, ACD, TRF1 and TRF2, have shown strong association with telomere attrition in T2DM and its pathophysiology, in these studies. However, the assessment is made within limited ethnicities (Caucasians, Han Chinese cohort and Punjabi Sikhs from South Asia), warranting the study of such associations in different ethnic groups. Here, we propose the possible mechanisms, in the light of existing knowledge, to understand the association of T2DM with telomeres and associated pathways. KEYWORDS: Type 2 Diabetes Mellitus (T2DM); Telomeres; Telomere attrition; Telomere maintenance genes.

1) Introduction Type 2 diabetes mellitus is a complex multifactorial disease characterized by hyperglycemia, which results from impaired insulin action or secretion [1]. Globally 387 million people have been estimated to suffer from diabetes and the number is expected to increase to 592 million by 2035. India has approximately 66.8 million individuals with diabetes, which may rise to more than 110 million by 2035, plausibly due to unparalleled rates of urbanization and lifestyle factors [2]. Intake of high calorie food, less physical activity and stressful environment have been suggested to be the major contributors [3]. Substantial evidences exist to justify that besides environmental factors, genetic components are critically involved in pathogenesis of T2DM. High concordance rate in monozygotic twins (96%) and general estimates of heritability (0.49) clearly indicate the role of heredity in T2DM [4]. In addition, over 200 genetic loci have been associated with T2DM worldwide, where the majority play a role in at least one of the mechanisms involved in maintaining blood glucose level, such as insulin regulation, insulin secretion, insulin uptake, insulin action, glucose metabolism, lipid metabolism, protein metabolism, mitochondrial function and inflammatory pathways [5]. However, a lot of genetic heterogeneity has been noticed across the populations; and only PPARG, KCNJ11 and TCF7L2 have been identified as genes associated with T2DM in most of the world populations [6]. The advent of Genome Wide Association Studies (GWAS) and Next Generation Sequencing has provided us an opportunity to identify new T2DM genetic loci and metabolic pathways. GWAS in T2DM has contributed ~60 loci robustly associated with T2DM. However, collectively these loci explain only ~10% of variance in disease susceptibility with the majority residing in the non-coding genome, suggesting that there remains a large integral part of genetic makeup yet to be explored for T2DM association [7]. Telomere genetics has recently emerged as an important area in T2DM pathophysiology, and it remains as one of the less explored genetic components. The main focus of this review is to highlight the genetic association of telomere shortening and associated pathways role in T2DM pathophysiology. 2) Telomere Biology Telomeres are protein DNA complexes situated at the terminal ends of the linear chromosomes which mainly function in the maintenance of genomic stability. In humans, telomeres are

guanine rich non-coding (TTAGGG) repeats. These are tandem DNA sequences which lengthen from 9 to 15 kb and terminate in a 50 to 500 nucleotide 3
single strand guanine overhang. The overhang gets folded and intrudes the double-stranded helix of telomere forming a T-loop. This facilitates the formation of a highly ordered structure mediating the end capping of the chromosomes [8]. The stability of the T-loop depends almost entirely on the integrity of the associated telomere maintenance proteins, referred to as the shelterin complex [9]. The telomere maintenance proteins constituting the shelterin complex include, Telomeric Repeat Binding Factor 1 (TRF1), Telomeric Repeat Binding Factor 2 (TRF2), Protection of Telomeres 1 (POT1), Tripeptidyl Peptidase 1 (TPP1), TRF1-Interacting Nuclear Factor 2 (TIN2) and Repressor Activator Protein 1 (RAP1) [10]. TRF1 and TRF2 bind to the double stranded telomeric DNA segment as homodimers. TRF1 acts as negative regulator of telomere length by inhibiting the action of telomerase [8] and TRF2 is involved in the T-loop stability. Disruption of TRF2 results in the activation of Ataxia Telangiectasia Mutated (ATM) protein mediated DNA damage signal which causes end-to-end telomere fusion and telomere homologous recombination, leading to the telomere sister-chromatid exchange (T-SCE) [9]. The repressor activator protein 1 (RAP1) binds directly with the TRF2 protein and is required for the efficient binding of TRF2 protein to the telomeric DNA, improving its efficacy [11]. Whereas, POT1 binds to the single stranded G overhang of telomeric DNA, helping in the formation of T-loop and protecting the chromosome ends from fusion and recombination [12]. The TPP1 binds with the POT1 protein, and helps in the recruitment of telomerase to the telomeric DNA, thus contributing to the protection of telomeres [13]. Disruption of both POT1 and TPP1 is known to result in the activation of ataxia telangiectasia and Rad-3 related (ATR) damage response and telomere fusion [14]. TRF-interacting nuclear factor 2 (TIN2) protein binds with TRF1, TRF2 and TPP1, acting as a central component of the shelterin complex and bridging all these proteins of the shelterin complex together [8]. The shelterin complex has an eminent role in the protection of chromosomes from DNA damagerepair system factors to protect the cells from cell cycle arrest and chromosomal instability [15]. In addition to protect the chromosomal ends, shelterin complex controls the synthesis of telomeric DNA by telomerase through cis-acting effect of TRF1 (Figure 1). Shelterin proteins potentially regulate telomere elongation by recruiting Telomerase, which is a ribonucleoprotein

complex consisting of reverse transcriptase (TERT) and an RNA component (TERC). Telomerase is inactive and suppressed in most of the normal somatic cells. It gets activated during the S phase of cell cycle and promotes the replication of telomeric DNA, which is not replicated by DNA polymerase during the replication process [16]. The telomeric DNA is further synthesized by telomerase through addition of the nucleotides at the 3' end of the telomeric DNA [17]. The mechanism involves Tankyrase or TRF1 Interacting Ankyrin-Related ADP-Ribose Polymerase (TNKS), that acts as antagonist to TRF1 (negative regulator) and positively regulates the telomere length. It has two forms, TNKS1 and TNKS2; both the forms interact with TRF1. TNKS ribosylates the TRF1 protein and causes its degradation. Degradation of TRF1 leads to the disintegration of shelterin complex. Thus the complex is no longer in a position to inhibit Telomerase; and in turn helps in the elongation of telomere length (Figure 2) [18]. During cell cycle progression, phosphorylation of TPP1 enhances the Telomerase recruitment and telomere elongation [16]. Depletion of TPP1 and TIN2 reduces the association of TERT with telomeres and their elongation, indicating that both are required for telomerase recruitment [19], however, its molecular basis still needs to be defined. 3) Telomere Length, Heredity and Diseases Telomere length decreases with each cell division. The decrease in length of the telomeres is by around 30-200 base pairs per cell division [20] and that particular length is usually attained by the Hayflick limit of cell division [21]. This telomere shortening, coinciding with the age of a cell, leads to the process called senescence or cell death. Telomere shortening is not only attributed to the cell division or aging, but also to the DNA damage caused by the oxidative stress. The 3‫ ׳‬single strand overhangs of the telomeres, being G rich region, are prone to oxidative damage that cause single strand breaks. During replication process, loss of these single strand break region lead to telomere attrition [22]. The rate of telomere shortening is also dependent on the length of the 3‫ ׳‬G rich single strand overhangs as the rate of shortening is directly proportional to the size of the overhang [23]. Physical activity to some extent modulates the telomere length by enhancing the antioxidant enzyme activity, thereby producing adequate antioxidants and down regulating the production of oxidants, stress and inflammation [24]. Other factor contributing to the telomere attrition is obesity, that is one of the leading causes of age related diseases and mortality. The underlying mechanism is the production of reactive oxygen

species (ROS), increased oxidative stress, alteration in the metabolic processes and production of pro-inflammatory cytokines [25]. The attrition of telomeres is greatly influenced by environmental factors and also a sedentary lifestyle, smoking habits, and dietary habits affect the telomere length and accelerate its attrition [24]. Telomere length also varies from individual to individual and it is notably short in older individuals. The variable telomere length is contributed by strong genetic component as suggested by high heritability up to 80%. The high heritability is also supported by a recent study, where closely related individuals of the long-lived persons showed longer lives and also had long telomeres and vice-versa [26]. Telomere length is regulated by the genes involved in telomere biology and variations in such genes have been extensively linked with attrition of telomeres in complex and age related disorders, such as Idiopathic pulmonary fibrosis, Cancers, Cardiovascular diseases, Atherosclerosis and Diabetes (Table 1 and 2)[15]. In age related diseases, telomere shortening increases which may have negative impact on the affected either by increasing the severity of the disease or pre-disposing the individual to other diseases or factors [27]. Interestingly, telomere shortening and T2DM are predisposed to common environmental risk factors, suggesting their strong association with each other. Moreover both are associated with oxidative stress and inflammation. 4) Telomere Attrition and T2DM Genetics Telomere attrition is associated with T2DM and its related conditions, like insulin resistance, impaired glucose tolerance, obesity and inflammation. Telomere attrition in individuals shows inverse correlation with HOMA-IR and Glycated hemoglobin (HbA1c) [28]. In a ~5 year follow up study, individuals who developed diabetes showed a significantly shorter leukocyte telomere length [29]. Cell damage due to hyperglycemia accelerates the shortening and there is pronounced attrition in T2DM individuals with complications of, retinopathy, atherosclerosis and depression. Adiposity in individuals with T2DM is marked with insulin resistance and production of ROS, generating oxidative stress and ultimately contributing to the shortening of telomeres. Short leukocyte telomere length in T2DM has been reported in many studies and is an independent risk factor of T2DM [30, 31]. Individuals with T2DM also show significant decrease of telomere length in the peripheral monocytes and endothelial cells [22]. Two GWAS have been performed in the framework of telomere attrition in T2DM, showing a strong association of telomere attrition with T2DM [32, 33]. Ahmed et al (2012) showed an inverse

relationship between leukocyte telomere length and 2 hour glucose concentration, i.e. longer the leukocyte telomere length lesser the concentration of glucose [34]. In a recent study, it has been shown that the individuals with T2DM have more illustrious signs of vascular ageing due to the shortening of telomeres [35]. The need for insulin production has been shown to increase with the increase in insulin resistance and is accomplished by the expansion in the pancreatic β-cell number. But decline in the pancreatic β-cell mass with the age leads to decrease in insulin production and glucose intolerance followed by T2DM [36]. Pancreatic β-cell dysfunction was related to telomere attrition, as was suggested by the mice model [37] and in the human pancreatic tissues (autopsied) with a

rate of loss in human pancreatic tissue of 36bp/year [38]. Telomere

shortening affects mitochondrial ATP production (less production of ATP) and Calcium regulation that hinders with release of insulin in spite of intact β-cells [37]. Presence of endoplasmic reticulum stress (misfolded protein) and deficiency of telomerase activity evokes the cell apoptosis and β-cell deterioration leading to T2DM [37, 39]. A study on RAP1 deficient mice suggests that RAP1 plays a role in the metabolic regulation leading to obesity and insulin resistance with the advancement of age [40]. Also, TERT is implicated in the signaling pathways that regulate the glucose utilization and is constitutively associated with some glucose transporters (GLUT) [41]. A member of sirtuin family, SIRT1, which is a nictotinamide adenine dinucleotide (NAD)-dependent deacetylase and ADP-ribosyltransferase has been reported recently as a master switch regulating etiology of T2DM [42]. It is involved in the regulation of several processes including metabolism (glucose-lipid metabolism), inflammation, mitochondrial biogenesis, circadian rhythms, stress resistance, autophagy, apoptosis and chromatin silencing [43]. SIRT1 has also been reported to be involved in the positive regulation of telomere length [44], playing an interesting role in both T2DM and telomere biology. In pancreatic β cells, it regulates the insulin secretion and protects the β cells from oxidative stress [45] as there is more production of ROS in aged and obese individuals [46] and the increased oxidative stress is associated with diabetes and metabolic disorders. Functional promoter variant of UCP2 also has been associated with short telomere length in T2DM, that is partly attributed to the increased oxidative stress [47]. Oxidative stress shortens the telomere length and decreases the mRNA level of TERT in adipocytes [48].

Interestingly, the genes: ADAMTS9, BCL2, FTO, and HMGA2, which are associated with T2DM, also show association with telomere independently. ADAMTS9 is a metalloproteinase, associated with decrease in the insulin sensitivity of peripheral tissues and a predictive locus that may represent the leukocyte telomere length [49, 50]. High glucose level regulates the action of BCL family anti-apoptotic and pro-apoptotic proteins, favoring the β-cells’ apoptosis. Bcl-2 in synergistic effect with Bcl-xL suppresses the insulin secretion signaling and is implicated in regulating telomerase activity [51, 52]. FTO is strongly associated with body mass index (BMI), obesity and T2DM and with shorter relative telomere length [53, 54]. HMGA2 is a transcription regulating factor which is involved in the islet functioning and insulin action [55]. It modulates the telomerase activity by regulating the hTERT expression and prevents the shortening of telomeres [56]. The role of T2DM associated genes in telomere biology puts forth to understand the details, whether T2DM is responsible for exacerbated shortening of telomere or telomere shortening predisposes the individual to T2DM. Telomere attrition is also attributed to the genes maintaining the telomere length. In a study, the association of 150 tagging-SNPs (tSNPs) of 11 telomere regulating-pathway genes (TERC, UCP1, TERT, POT1, TNKS, TRF1, TNKS2, TEP1, ACD, TRF2 and TRF2IP) and incidence of T2DM was investigated in 22,715 Caucasian female participants of the prospective Women’s Genome Health Study. The study demonstrated that the genetic heterogeneity within the genes, TRF1, TNKS, TEP1, ACD, and TRF2, in particular, TRF1 and TEP1 were associated with T2DM risk [57]. A study reported an association of TERC haplotype with higher risk of both T2DM and coronary heart disease (Table 2 & 3) [58]. Two GWAS have confirmed the association of telomere genes CSNK2A2 and TERT with T2DM in Punjabi Sikhs Indian population and Han Chinese population respectively (Table 2) [32, 33]. These associations of gene involved in telomere regulation pathway as well as various independent association of genes with both T2DM and telomeres/telomere length, clearly indicate an overlap exists. Further an interesting perspective to explore could be whether the genes are directly affecting the T2DM susceptibility or indirectly through telomeres.

5) Limitations of the previous studies and future perspectives T2DM with a worldwide burden needs to be well studied and explored with great emphasis on the role of genetic factors participating in the causation of the disease. Above 200 loci have been linked with T2DM worldwide, of these ~60 loci have been identified and confirmed by GWAS [7]. However, these loci describe only ~10% variance suggesting that large integral part of genome is yet to be explored for T2DM association. The preset stringent statistical significance level for GWAS i.e. P value < ~1
10-8 excludes all those genetic risk factors with moderate effect or possibly strong effect in case of particular ethnic groups, towards disease susceptibility. Moreover, GWAS has been limited to common variants that ignore other important risk factors playing role in the pathogenesis of disease. Such limitations of GWAS can be resolved to some extent by evaluating these overlooked associations in different ethnicities. Despite the fact that telomere attrition does play major role in the pathogenesis of T2DM [59], the association of telomere maintenance genes with T2DM is evaluated in limited ethnic groups. Further, functional studies are required to evaluate the role of telomeres and telomere attrition in T2DM, since it is still not clear whether the attrition is a cause or consequence of T2DM. 6) Conclusion Telomere maintenance genes seem to be amongst the overlooked genetic factors in GWAS that are critical to study in well-stratified populations of different ethnic groups by case-control association studies. Studying the role of telomere maintenance genes in T2DM pathogenesis will add to our understanding of genetic landscape of diabetes and may highlight the new pathway, other than the conventional pathways, associated with the disease. Associated genes could then be targeted for development of new therapeutic strategies. Acknowledgment All Authors acknowledge support of their respective institutions. IS acknowledge the financial assistantship from SMVDU for her Ph.D. thesis work. SS and ER acknowledge the Startup Grants from UGC, India and SS acknowledge the SERB-DST India Young Scientist Research Grant Award. Conflict of Interest: none

References [1] Hara K, Shojima N, Hosoe J, Kadowaki T. Genetic architecture of type 2 diabetes. Biochemical and biophysical research communications. 2014;452:213-20. [2] Forouhi NG, Wareham NJ. Epidemiology of diabetes. Medicine. 2014;42:698-702. [3] Mahajan A, Sharma S, Dhar MK, Bamezai RN. Risk factors of type 2 diabetes in population of Jammu and Kashmir, India. J Biomed Res. 2013;27:372-9. [4] Sanghera DK, Blackett PR. Type 2 Diabetes Genetics: Beyond GWAS. Journal of diabetes & metabolism. 2012;3. [5] Lin Y, Sun Z. Current views on type 2 diabetes. The Journal of endocrinology. 2010;204:1-11. [6] Brunetti A, Chiefari E, Foti D. Recent advances in the molecular genetics of type 2 diabetes mellitus. World journal of diabetes. 2014;5:128-40. [7] Hara K, Fujita H, Johnson TA, Yamauchi T, Yasuda K, Horikoshi M, et al. Genome-wide association study identifies three novel loci for type 2 diabetes. Hum Mol Genet. 2014;23:239-46. [8] Palm W, de Lange T. How shelterin protects mammalian telomeres. Annual review of genetics. 2008;42:301-34. [9] de Lange T. Shelterin: the protein complex that shapes and safeguards human telomeres. Genes Dev. 2005;19:2100-10. [10] Choi KH, Farrell AS, Lakamp AS, Ouellette MM. Characterization of the DNA binding specificity of Shelterin complexes. Nucleic Acids Res. 2011;39:9206-23. [11] Janouskova E, Necasova I, Pavlouskova J, Zimmermann M, Hluchy M, Marini V, et al. Human Rap1 modulates TRF2 attraction to telomeric DNA. Nucleic Acids Res. 2015;43:2691-700. [12] He Q, Zeng P, Tan JH, Ou TM, Gu LQ, Huang ZS, et al. G-quadruplex-mediated regulation of telomere binding protein POT1 gene expression. Biochim Biophys Acta. 2014;1840:2222-33. [13] Zhang Y, Chen LY, Han X, Xie W, Kim H, Yang D, et al. Phosphorylation of TPP1 regulates cell cycledependent telomerase recruitment. Proceedings of the National Academy of Sciences of the United States of America. 2013;110:5457-62. [14] Kibe T, Osawa GA, Keegan CE, de Lange T. Telomere protection by TPP1 is mediated by POT1a and POT1b. Mol Cell Biol. 2010;30:1059-66. [15] Zhu H, Belcher M, van der Harst P. Healthy aging and disease: role for telomere biology? Clinical science. 2011;120:427-40. [16] Zhang Y, Chen L-Y, Han X, Xie W, Kim H, Yang D, et al. Phosphorylation of TPP1 regulates cell cycledependent telomerase recruitment. Proceedings of the National Academy of Sciences. 2013;110:545762. [17] Nandakumar J, Cech TR. Finding the end: recruitment of telomerase to telomeres. Nat Rev Mol Cell Biol. 2013;14:69-82. [18] Diotti R, Loayza D. Shelterin complex and associated factors at human telomeres. Nucleus. 2011;2:119-35. [19] Abreu E, Aritonovska E, Reichenbach P, Cristofari G, Culp B, Terns RM, et al. TIN2-tethered TPP1 recruits human telomerase to telomeres in vivo. Mol Cell Biol. 2010;30:2971-82. [20] Nan H, Du M, De Vivo I, Manson JE, Liu S, McTiernan A, et al. Shorter telomeres associate with a reduced risk of melanoma development. Cancer research. 2011;71:6758-63. [21] Hayflick L, Moorhead PS. The serial cultivation of human diploid cell strains. Exp Cell Res. 1961;25:585-621. [22] Sampson MJ, Winterbone MS, Hughes JC, Dozio N, Hughes DA. Monocyte telomere shortening and oxidative DNA damage in type 2 diabetes. Diabetes Care. 2006;29:283-9. [23] Huffman KE, Levene SD, Tesmer VM, Shay JW, Wright WE. Telomere shortening is proportional to the size of the G-rich telomeric 3'-overhang. J Biol Chem. 2000;275:19719-22.

[24] Ludlow AT, Roth SM. Physical Activity and Telomere Biology: Exploring the Link with Aging-Related Disease Prevention. Journal of Aging Research. 2011;2011:790378. [25] Tzanetakou IP, Katsilambros NL, Benetos A, Mikhailidis DP, Perrea DN. "Is obesity linked to aging?": adipose tissue and the role of telomeres. Ageing Res Rev. 2012;11:220-9. [26] Honig LS, Kang MS, Cheng R, Eckfeldt JH, Thyagarajan B, Leiendecker-Foster C, et al. Heritability of telomere length in a study of long-lived families. Neurobiol Aging. 2015. [27] Shammas MA. Telomeres, lifestyle, cancer, and aging. Current Opinion in Clinical Nutrition and Metabolic Care. 2011;14:28-34. [28] Gardner JP, Li S, Srinivasan SR, Chen W, Kimura M, Lu X, et al. Rise in insulin resistance is associated with escalated telomere attrition. Circulation. 2005;111:2171-7. [29] Zhao J, Zhu Y, Lin J, Matsuguchi T, Blackburn E, Zhang Y, et al. Short leukocyte telomere length predicts risk of diabetes in american indians: the strong heart family study. Diabetes. 2014;63:354-62. [30] Adaikalakoteswari A, Balasubramanyam M, Mohan V. Telomere shortening occurs in Asian Indian Type 2 diabetic patients. Diabet Med. 2005;22:1151-6. [31] Al-Attas OS, Al-Daghri NM, Alokail MS, Alfadda A, Bamakhramah A, Sabico S, et al. Adiposity and insulin resistance correlate with telomere length in middle-aged Arabs: the influence of circulating adiponectin. Eur J Endocrinol. 2010;163:601-7. [32] Liu Y, Cao L, Li Z, Zhou D, Liu W, Shen Q, et al. A genome-wide association study identifies a locus on TERT for mean telomere length in Han Chinese. PLoS One. 2014;9:e85043. [33] Saxena R, Bjonnes A, Prescott J, Dib P, Natt P, Lane J, et al. Genome-wide association study identifies variants in casein kinase II (CSNK2A2) to be associated with leukocyte telomere length in a Punjabi Sikh diabetic cohort. Circ Cardiovasc Genet. 2014;7:287-95. [34] Ahmad S, Heraclides A, Sun Q, Elgzyri T, Ronn T, Ling C, et al. Telomere length in blood and skeletal muscle in relation to measures of glycaemia and insulinaemia. Diabetic medicine : a journal of the British Diabetic Association. 2012;29:e377-81. [35] Dudinskaya EN, Tkacheva ON, Shestakova MV, Brailova NV, Strazhesko ID, Akasheva DU, et al. Short telomere length is associated with arterial aging in patients with type 2 diabetes mellitus. Endocr Connect. 2015. [36] Gunasekaran U, Gannon M. Type 2 Diabetes and the Aging Pancreatic Beta Cell. Aging (Albany NY). 2011;3:565-75. [37] Guo N, Parry EM, Li LS, Kembou F, Lauder N, Hussain MA, et al. Short telomeres compromise betacell signaling and survival. PLoS One. 2011;6:e17858. [38] Ishii A, Nakamura K, Kishimoto H, Honma N, Aida J, Sawabe M, et al. Telomere shortening with aging in the human pancreas. Exp Gerontol. 2006;41:882-6. [39] Kuhlow D, Florian S, von Figura G, Weimer S, Schulz N, Petzke KJ, et al. Telomerase deficiency impairs glucose metabolism and insulin secretion. Aging. 2010;2:650-8. [40] Yeung F, Ramírez Cristina M, Mateos-Gomez Pedro A, Pinzaru A, Ceccarini G, Kabir S, et al. Nontelomeric Role for Rap1 in Regulating Metabolism and Protecting against Obesity. Cell Reports. 2013;3:1847-56. [41] Shaheen F, Grammatopoulos DK, Muller J, Zammit VA, Lehnert H. Extra-nuclear telomerase reverse transcriptase (TERT) regulates glucose transport in skeletal muscle cells. Biochim Biophys Acta. 2014;1842:1762-9. [42] Ali S, Nafis S, Kalaiarasan P, Rai E, Sharma S, Bamezai RNK. Understanding Genetic Heterogeneity in Type 2 Diabetes by Delineating Physiological Phenotypes – SIRT1 and its Gene Network in Impaired Insulin Secretion. The Review of DIABETIC STUDIES. 2015;(Accepted). [43] Dong XC. Sirtuin biology and relevance to diabetes treatment. Diabetes Manag (Lond). 2012;2:24357.

[44] Palacios JA, Herranz D, De Bonis ML, Velasco S, Serrano M, Blasco MA. SIRT1 contributes to telomere maintenance and augments global homologous recombination. J Cell Biol. 2010;191:1299-313. [45] Rai E, Sharma S, Kaul S, Jain K, Matharoo K, Bhanwer AS, et al. The interactive effect of SIRT1 promoter region polymorphism on type 2 diabetes susceptibility in the North Indian population. PLoS One. 2012;7:e48621. [46] Singh T, Newman AB. Inflammatory markers in population studies of aging. Ageing research reviews. 2011;10:319-29. [47] Salpea KD, Talmud PJ, Cooper JA, Maubaret CG, Stephens JW, Abelak K, et al. Association of telomere length with type 2 diabetes, oxidative stress and UCP2 gene variation. Atherosclerosis. 2010;209:42-50. [48] Monickaraj F, Aravind S, Nandhini P, Prabu P, Sathishkumar C, Mohan V, et al. Accelerated fat cell aging links oxidative stress and insulin resistance in adipocytes. Journal of Biosciences. 2013;38:113-22. [49] Boesgaard TW, Gjesing AP, Grarup N, Rutanen J, Jansson PA, Hribal ML, et al. Variant near ADAMTS9 known to associate with type 2 diabetes is related to insulin resistance in offspring of type 2 diabetes patients--EUGENE2 study. PLoS One. 2009;4:e7236. [50] Zhu Y, Voruganti VS, Lin J, Matsuguchi T, Blackburn E, Best LG, et al. QTL mapping of leukocyte telomere length in American Indians: The Strong Heart Family Study. Aging (Albany NY). 2013;5:704-16. [51] Ohmura Y, Aoe M, Andou A, Shimizu N. Telomerase activity and Bcl-2 expression in non-small cell lung cancer. Clin Cancer Res. 2000;6:2980-7. [52] Luciani DS, White SA, Widenmaier SB, Saran VV, Taghizadeh F, Hu X, et al. Bcl-2 and Bcl-xL suppress glucose signaling in pancreatic beta-cells. Diabetes. 2013;62:170-82. [53] Dlouha D, Pitha J, Lanska V, Hubacek JA. Association between FTO 1st intron tagging variant and telomere length in middle aged females. 3PMFs study. Clinica Chimica Acta. 2012;413:1222-5. [54] Prakash J, Srivastava N, Awasthi S, Agarwal CG, Natu SM, Rajpal N, et al. Association of FTO rs17817449 SNP with obesity and associated physiological parameters in a north Indian population. Ann Hum Biol. 2011;38:760-3. [55] Alkayyali S, Lajer M, Deshmukh H, Ahlqvist E, Colhoun H, Isomaa B, et al. Common variant in the HMGA2 gene increases susceptibility to nephropathy in patients with type 2 diabetes. Diabetologia. 2013;56:323-9. [56] Li AY, Lin HH, Kuo CY, Shih HM, Wang CC, Yen Y, et al. High-mobility group A2 protein modulates hTERT transcription to promote tumorigenesis. Mol Cell Biol. 2011;31:2605-17. [57] Zee RY, Ridker PM, Chasman DI. Genetic variants of 11 telomere-pathway gene loci and the risk of incident type 2 diabetes mellitus: the Women's Genome Health Study. Atherosclerosis. 2011;218:144-6. [58] Maubaret CG, Salpea KD, Romanoski CE, Folkersen L, Cooper JA, Stephanou C, et al. Association of TERC and OBFC1 haplotypes with mean leukocyte telomere length and risk for coronary heart disease. PLoS One. 2013;8:e83122. [59] Willeit P, Raschenberger J, Heydon EE, Tsimikas S, Haun M, Mayr A, et al. Leucocyte telomere length and risk of type 2 diabetes mellitus: new prospective cohort study and literature-based meta-analysis. PLoS One. 2014;9:e112483. [60] Codd V, Nelson CP, Albrecht E, Mangino M, Deelen J, Buxton JL, et al. Identification of seven loci affecting mean telomere length and their association with disease. Nat Genet. 2013;45:422-7, 7e1-2. [61] Walsh KM, Codd V, Smirnov IV, Rice T, Decker PA, Hansen HM, et al. Variants near TERT and TERC influencing telomere length are associated with high-grade glioma risk. Nat Genet. 2014;46:731-5. [62] Fingerlin TE, Murphy E, Zhang W, Peljto AL, Brown KK, Steele MP, et al. Genome-wide association study identifies multiple susceptibility loci for pulmonary fibrosis. Nat Genet. 2013;45:613-20. [63] Hu Z, Wu C, Shi Y, Guo H, Zhao X, Yin Z, et al. A genome-wide association study identifies two new lung cancer susceptibility loci at 13q12.12 and 22q12.2 in Han Chinese. Nat Genet. 2011;43:792-6.

[64] Speedy HE, Di Bernardo MC, Sava GP, Dyer MJ, Holroyd A, Wang Y, et al. A genome-wide association study identifies multiple susceptibility loci for chronic lymphocytic leukemia. Nat Genet. 2014;46:56-60. [65] Figueroa JD, Ye Y, Siddiq A, Garcia-Closas M, Chatterjee N, Prokunina-Olsson L, et al. Genome-wide association study identifies multiple loci associated with bladder cancer risk. Hum Mol Genet. 2014;23:1387-98. [66] Chubb D, Weinhold N, Broderick P, Chen B, Johnson DC, Forsti A, et al. Common variation at 3q26.2, 6p21.33, 17p11.2 and 22q13.1 influences multiple myeloma risk. Nat Genet. 2013;45:1221-5. [67] Sawcer S, Hellenthal G, Pirinen M, Spencer CC, Patsopoulos NA, Moutsianas L, et al. Genetic risk and a primary role for cell-mediated immune mechanisms in multiple sclerosis. Nature. 2011;476:214-9. [68] Codd V, Mangino M, van der Harst P, Braund PS, Kaiser M, Beveridge AJ, et al. Common variants near TERC are associated with mean telomere length. Nat Genet. 2010;42:197-9. [69] Levy D, Neuhausen SL, Hunt SC, Kimura M, Hwang SJ, Chen W, et al. Genome-wide association identifies OBFC1 as a locus involved in human leukocyte telomere biology. Proc Natl Acad Sci U S A. 2010;107:9293-8. [70] Soerensen M, Thinggaard M, Nygaard M, Dato S, Tan Q, Hjelmborg J, et al. Genetic variation in TERT and TERC and human leukocyte telomere length and longevity: a cross-sectional and longitudinal analysis. Aging Cell. 2012;11:223-7. [71] Prescott J, Kraft P, Chasman DI, Savage SA, Mirabello L, Berndt SI, et al. Genome-wide association study of relative telomere length. PLoS One. 2011;6:e19635. [72] Mangino M, Hwang SJ, Spector TD, Hunt SC, Kimura M, Fitzpatrick AL, et al. Genome-wide metaanalysis points to CTC1 and ZNF676 as genes regulating telomere homeostasis in humans. Hum Mol Genet. 2012;21:5385-94. [73] Mirabello L, Yu K, Kraft P, De Vivo I, Hunter DJ, Prescott J, et al. The association of telomere length and genetic variation in telomere biology genes. Human mutation. 2010;31:1050-8. [74] Ding H, Yan F, Zhou LL, Ji XH, Gu XN, Tang ZW, et al. Association between previously identified loci affecting telomere length and coronary heart disease (CHD) in Han Chinese population. Clin Interv Aging. 2014;9:857-61. [75] Shen Q, Zhang Z, Yu L, Cao L, Zhou D, Kan M, et al. Common variants near TERC are associated with leukocyte telomere length in the Chinese Han population. Eur J Hum Genet. 2011;19:721-3.

Figure legends: Figure 1: Components of Shelterin Complex – TRF1, TRF2, RAP1, POT1, TPP1 and TIN2. Shelterin complex controls the telomeric DNA synthesis. Telomerase consists of subunits namely TERT, TERC and Dyskerin (DKC1). TRF1, TRF2, RAP1 and TIN2 components of Shelterin complex inhibits Telomerase complex from replicating the end of chromosomes. Adopted from [8] Figure 2: Elongation of Telomeres: TNKS Poly (ADP) ribosylates TRF1 protein due to which it gets degraded and the Shelterin complex no longer is able to inhibit the telomerase. Telomerase bind at the 3ˈ end of the overhang and replicates the telomeres. Adopted from [18]

Table1: Telomere Maintenance genes associated with different types of disorders Gene

Role of Gene

SNPs

Role of SNP

Associated Allele

Associated Disease/Phenotype

Population

Sample Size

P-Value

Ref

TERT

Telomere replication

rs2736100

intron variant, UTR 5 variant

A

Idiopathic Pulmonary Fibrosis*

European Cohorts

48,423

4.38×10-19

[60]

C

Glioma*

9,380

1
10-15

[61]

A

8,610

2
10-19

[62]

C

Interstitial lung disease* Lung Cancer*

18,130

1
10-27

[63]

T

Telomere Length*

48,423

2.54×10-31

[60]

C

Chronic Lymphocytic Leukemia* Bladder Cancer*

European Ancestry European Ancestry Han Chinese Ancestry European Cohorts European Ancestry

11,233

2
10-9

[64]

European Ancestry European Ancestry European Ancestry European Cohorts European Cohort Danish European Cohort

20,837

5
10-9

[65]

9,112

9
10-14

[66]

38,135

7
10-7

[67]

12,409

3.72×10-14

[68]

8,186

1.57×10-4

[69]

1,905 6,014

0.014 1.5×10-14

[70] [71]

European Cohort European Cohort

12,409

2.79×10-12

[68]

6,014

1.6×10-13

[71]

European Cohort Danish

8,186

1.1×10-5

[69]

TERC

Telomere replication

rs10936599

non coding transcript, UTR 5 variant

G

Multiple Myeloma* Multiple Sclerosis

rs12696304

rs16847897

Telomere Length*

C

Age Related Disease* Telomere Length Prostate, Lung, Colorectal & Ovarian Cancer* Telomere Length* Prostate, Lung, Colorectal & Ovarian Cancer* Age Related Disease* Telomere Length

Intron variant

A

1,905

0.011

[70]

rs1317082

Intron Variant Intron variant

G

Telomere Length

European

11,416

1
10-8

[72]

C

Prostate, Lung, Colorectal & Ovarian Cancer

Caucasian & NonHispanic

3,646

0.009

[73]

Intron variant UTR-5 variant

A

Telomere Length*

48,423

6.9×10-11

[60]

A

8,186

2.33×10-11

[69]

T

Telomere Length/Age Related Disease* Telomere Length

European Cohort European Cohort European

11,416

9
10-11

[72]

A

Telomere Length*

European Cohort Han Chinese

48,423

4.35×10-16

[60]

3,984

0.012

[74]

Telomere elongation

rs11249943

OBFC1

Activator of DNA polymerase-α primase

rs9420907 rs4387287

rs9419958 Assembly of Telomere Complex

Intron variant

G

rs3772190

TNKS

NAF1

Upstream variant

rs7675998

Intron variant Intron variant

CHD with history of T2DM

CTC1

Telomere maintenance

rs3027234

Intron variant

T

Telomere Length*

European

11,416

2
10-8

[72]

* GWAS; CHD- Coronary Heart disease

Table2: Association of SNPs in Telomere Maintenance Genes with T2DM. Gene

Role of Gene

SNP

Role of SNP

Associated Allele

Associated Disease/Phenotype

Population

Sample Size

P-Value

Ref

TERT

Telomere replication Telomere replication

rs2736100

UTR-5 variant Upstream variant

C

T2DM*

7,245

4.45×10-6

[32]

G

T2DM

Han Chinese Cohort Han Chinese

4,016

4.5×10-3

[75]

Intron variant Near gene-5, noncoding transcript variant Missense, noncoding transcript variant Intron Variant Intron variant Upstream variant Intron variant Intron variant Missense variant Upstream variant

C

rs7202185

TERC

rs12696304

rs16847897 TEP1

Telomerase Activity

rs3093872

rs3093921

rs1713423 rs1713434 TRF1

Inhibits telomere elongation

rs2010441 rs10099824 rs3863242 rs2291219

TRF2

ACD

TNKS2

CSNK2A2

*GWAS

A

9.5×10-5 T2DM

Caucasian

22,715

0.0369

G

0.0346

A

0.0496

G

0.0291

A

0.0032

A

0.0088

A

0.0083

A

0.0265

A

0.0001

Near gene-3

A

0.0049

0.016

Inhibit telomere elongation Telomere length maintenance Telomere elongation

rs4783704

rs1539041

Intron variant

A

Telomere regulation and maintenance

rs74019828

Intron variant

A

T2DM*

Punjabi Sikhs from South Asia

8,026

4.5×10-8

[57]

[33]

Table3: Association of Haplotypes of Telomere Maintenance Genes with T2DM Gene

Haplotype

Role of SNP

TRF1

rs6982126

Intron variant Intron variant Intron variant UTR 3 variant Missense Intron variant Intron variant Upstream variant Intron variant Intron variant

rs10099824 rs3863243 rs2291220

TEP1

rs2291219 rs1713423 rs4982038

TERC

rs12696304 rs10936601 rs16847897

Associated Allele of Haplotypes A

Associated Phenotype/Disease

Population

Sample Size

P-value

Ref.

T2DM

Caucasian

22,715

0.0054

[57]

A A G A A

0.0375

A G T C

T2DM

European

2,353

0.004

[58]

Highlights
The possible role of Telomere Maintenance Genes and associated pathways in Type 2 Diabetes Mellitus is proposed.
Mechanism of telomere attrition in Type 2 Diabetes Mellitus is proposed.
Understanding the role of telomere maintenance genes in T2DM pathogenesis will add to our understanding of genetic landscape of diabetes.