Telomere Biology and Human Phenotype
Abstract
:1. Introduction: Structure, Function and Maintenance of the Telomere
2. Telomere Length and Replicative Capacity
3. Telomere Homeostasis Throughout a Life-Time
Telomere Length in Relation to Demographic and Lifestyle Factors
4. Telomere Length and Biological Aging
4.1. Telomere Biology and Premature Aging Disorders
4.2. Telomere Length in Age-Related Cardiometabolic and Neurological Disorders
4.3. Telomeres, Tumorigenesis and Cancer
5. Conclusions and Perspectives
Author Contributions
Funding
Conflicts of Interest
References
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Protein Name | Interactions | Function |
---|---|---|
Telomere repeat binding factor 1 (TERF1 also known as TRF1) | Direct interaction with double stranded TTAGGG repeats | Regulation of telomere length |
Telomere repeat binding factor 2 (TERF2 also known as TRF2) | Direct interaction with double stranded TTAGGG repeats | Stabilisation of the T-loop and regulation of telomere length |
TERF1 interacting nuclear factor 2 (TINF2 also known as TIN2) | Associates directly with TERF1, TERF2 and ACD and indirectly with POT1 | Tethering of ACD and POT1 to TERF1 and TERF2 and tethering TERF1 to TERF2, which stabilises the association of TERF2 with the telomere. Also regulates telomere length |
Protection of Telomeres 1 (POT1) | Direct interaction with single stranded telomere overhang | Inhibition of DNA damage response and regulation of telomere length |
Shelterin complex subunit and telomerase recruitment factor (ACD, also known as TPP1) | Interaction with TINF2 and POT1 | Enhances POT1 binding to single stranded telomere DNA and regulates telomere length in combination with POT1 |
TERF2 interacting protein (TERF2IP also known as RAP1) | Associates with TERF2 | Telomere length regulation |
Demographic Factors | General Observations | References |
---|---|---|
Genetic factors | Several twin studies have identified high heritability of telomere length and many specific loci associated with telomere length have been reported. | [64,65,66,67] |
Gender | Longer telomeres are found in adult females compared to males. This is thought to be due to higher levels of oestrogen, which confers anti-inflammatory as well as antioxidant properties and is known to promote telomerase expression. | [60,68,69,70] |
Ethnicity | Telomeres are slightly longer in white individuals compared to black and Hispanic individuals. However, this difference is often not statistically significant unless also adjusted for other factors such as age, sex, socio-economic background and lifestyle factors (diet and smoking) | [71] |
Level of psychosocial stress | Shortened telomeres are associated with high levels of psychosocial stress as a result of increased oxidative stress as well as reduced telomerase activity. Telomere length is also inversely correlated with major depressive disorder due to increased inflammatory factors leading to increased oxidative stress. | [72,73,74] |
Level of physical activity | Longer telomeres have been found in those that engage in higher levels of physical activity, which is associated with improved physical and psychological wellbeing. Thus it is possible that the effects of physical activity on telomere length are influenced by a positive effect on physical and mental well-being | [75,76,77] |
Obesity | Telomeres are known to be shortened in obese individuals. Obesity is associated with chronic inflammation, increased reactive oxygen species (ROS) production in adipose tissue and evidence of increased systemic oxidative stress. Furthermore, telomere length is correlated with body mass index (BMI), with increased BMI resulting in higher blood volume, stimulating increased proliferation of blood cells and leading to telomere shortening. Interestingly, weight loss is positively correlated with telomere lengthening and those with shortest telomere length at baseline benefit from the most pronounced rate of telomere lengthening following weight loss. A greater adherence to a Mediterranean diet is also associated with longer telomeres. | [78,79,80,81] |
Smoking | Telomere length is shorter in smokers and ex-smokers compared to non-smokers and negatively associated with the amount of cigarettes smoked per year. | [78,82] |
Alcohol consumption | Telomere length is negatively correlated with the number of alcohol units consumed per day and is shorter in alcohol abusers compared to controls. | [83] |
Premature Aging Disorder | Characteristic Symptoms | Mutations Observed | Effects on Telomere Structure | References |
---|---|---|---|---|
Hutchinson-Gilford Progeria Syndrome | Hair greying and loss, decreased joint mobility, loss of subcutaneous fat and atherosclerosis | Point mutation in the LMNA gene encoding prelamin A; a protein involved in nuclear lamina. Mutant LMNA induces DNA damage response at the telomere leading to cell senescence | Shortened telomere length | [91,92,93] |
Werner Syndrome | Hair greying and loss, skin atrophy, diabetes, osteoporosis, cataracts, arteriosclerosis and neoplasms | Mutation in WRN gene located on the P arm of chromosome 8, which encodes the RecQ DNA helicase involved in DNA replication, recombination and repair. Recruitment of WRN by TERF2 is essential for resolution of the telomeric D-loop and synthesis of the telomeric 3′ overhang | Average telomere length is not reduced. However, loss of telomeres on individual sister chromatids is observed leading to chromosome breakage-fusion events, genome instability and cell senescence. The rate of overall telomere attrition is also increased. | [94,95,96,97,98] |
Bloom Syndrome | Growth retardation, immunodeficiency, genomic instability cancer and premature menopause | Mutation of BLM; another RecQ helicase associated with TERF2 and involved in DNA replication, recombination and repair | Telomere length is not reduced. However, the rate of telomere shortening is accelerated | [99,100,101,102] |
Nijmegen Breakage Syndrome | Chromosomal instability and cancers | Mutation of NSB1, which is involved in DNA repair in association with TERF2 | Shortened telomere length | [103,104] |
Cockayne Syndrome | Neurological degeneration, hearing loss, retinal degeneration and loss of subcutaneous fat | Mutation in one of five genes including CSA, CSB, XPB, XPD and XPG. Mutation in CSB is implicated in the majority of cases. CSB interacts with TERF2 as well as TERF1 to regulate telomere length maintenance | Shortened telomere length | [105,106,107] |
Dyskeratosis Congenita | Abnormal skin pigmentation, nail dystrophy, bone marrow failure and cancer | One of several mutations involving telomerase (an enzyme involved in telomere length maintenance) or proteins that regulate telomerase. In the X-linked recessive form, DKC1 is mutated, which associates with TERC (the RNA component of telomerase). In the autosomal dominant form, TERC is commonly involved; however TIFN2 is mutated in some cases. In autosomal recessive forms, mutations in TERT (the reverse transcriptase component of telomerase), NOP10 and NHP2 are the cause. NHP2 interacts with NOP10, which in turn associates with DKC1 in order to interact with TERC. | Shortened telomere length. Furthermore, shorter telomeres are associated with more severe clinical phenotypes | [108,109,110,111,112] |
Ataxia telangiectasia | Neurological deterioration, chromosomal instability and predisposition to cancer | Mutations in ATM, which is located on the q arm of chromosome 11 and is involved in cell cycle progression and DNA repair pathways | Accelerated telomere shortening and chromosome fusion events | [113,114] |
Down’s Syndrome | Accelerated aging characteristics such as premature skin wrinkling, greying hair, hypogonadism, hypothyroidism, early menopause and declining immune function. In addition overexpression of amyloid precursor protein (APP) on chromosome 21 leads to Alzheimer’s Disease | Trisomy chromosome 21 | Shortened telomere length | [115,116,117] |
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Turner, K.J.; Vasu, V.; Griffin, D.K. Telomere Biology and Human Phenotype. Cells 2019, 8, 73. https://doi.org/10.3390/cells8010073
Turner KJ, Vasu V, Griffin DK. Telomere Biology and Human Phenotype. Cells. 2019; 8(1):73. https://doi.org/10.3390/cells8010073
Chicago/Turabian StyleTurner, Kara J., Vimal Vasu, and Darren K. Griffin. 2019. "Telomere Biology and Human Phenotype" Cells 8, no. 1: 73. https://doi.org/10.3390/cells8010073
APA StyleTurner, K. J., Vasu, V., & Griffin, D. K. (2019). Telomere Biology and Human Phenotype. Cells, 8(1), 73. https://doi.org/10.3390/cells8010073