Telomeres, Early-Life Stress and Mental Illness

Ridout, Samuel J.; Ridout, Kathryn K.; Kao, Hung‐Teh; Carpenter, Linda L.; Philip, Noah S.; Tyrka, Audrey R.; Price, Lawrence H.

doi:10.1159/000369088

Cited by 46 publications

(59 citation statements)

References 140 publications

(161 reference statements)

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“…These changes contribute to cellular senescence, apoptosis and cancer risk, signal increased inflammation, and ultimately contribute to organ dysfunction and risk for age-related conditions including diabetes and cardiovascular disease. Early or severe stress is associated with reductions in telomere length and maintenance, suggesting these exposures might accelerate the aging process (Ridout et al, 2015). New research supports the intriguing hypothesis that early stress may also affect mitochondrial function, further linking early stress and accelerated aging.…”

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confidence: 87%

“…Telomerase, an enzyme that maintains telomere length and modulates cell signaling, gene expression, and DNA damage responses, also influences mitochondrial proliferation and function (Sahin and DePinho, 2012). Telomerase activity changes with stress and other conditions altering neuroendocrine function (Ridout et al, 2015). Glucocorticoid exposure, and associated inflammatory and oxidative stress pathway activation, is linked with telomere shortening and may be a mechanism through which early stress contributes to telomere decline (Ridout et al, 2015).…”

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confidence: 99%

“…Telomerase activity changes with stress and other conditions altering neuroendocrine function (Ridout et al, 2015). Glucocorticoid exposure, and associated inflammatory and oxidative stress pathway activation, is linked with telomere shortening and may be a mechanism through which early stress contributes to telomere decline (Ridout et al, 2015). Glucocorticoid signaling is also involved in mitochondrial replication (Cai et al, 2015) and can damage mitochondria via elevating glucose levels, promoting systemic inflammation, altering gene expression in proapoptotic pathways, and hastening cellular aging (Picard et al, 2014).…”

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confidence: 99%

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The Cellular Sequelae of Early Stress: Focus on Aging and Mitochondria

Ridout

Carpenter

Tyrka

2015

Neuropsychopharmacol

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confidence: 87%

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confidence: 99%

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confidence: 99%

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The Cellular Sequelae of Early Stress: Focus on Aging and Mitochondria

Ridout

Carpenter

Tyrka

2015

Neuropsychopharmacol

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“…(41) After each cell division, the length of the telomere shortens, and when a critical shortening is reached, the cell enters senescence or apoptosis. (42,43) Thus, TL is considered a marker of cell senescence and replicative capacity. (42,44) LTL represents the average TL across a heterogeneous population of leukocytes including monocytes, granulocytes and lymphocytes, and can serve as a biological marker of aging.…”

Section: Telomeres and Telomerasementioning

confidence: 99%

“…(42,43) Thus, TL is considered a marker of cell senescence and replicative capacity. (42,44) LTL represents the average TL across a heterogeneous population of leukocytes including monocytes, granulocytes and lymphocytes, and can serve as a biological marker of aging. (45) and regulation of programmed cell death.…”

Section: Telomeres and Telomerasementioning

confidence: 99%

Telomeres and Telomerase in The Aging Heart

2017

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B ACKGROUND:Aging per se is a risk factor for reduced cardiac function and heart diseases, even when adjusted for aging-associated cardiovascular risk factors. Accordingly, aging-related biochemical and cell-biological changes lead to pathophysiological conditions, especially reduced heart function and heart disease. CONTENT:Telomere dysfunction induces a profound p53-dependent repression of the master regulators of mitochondrial biogenesis and function, peroxisome proliferator-activated receptor gamma coactivator (PGC)-1a and PGC-1b in the heart, which leads to bioenergetic compromise due to impaired oxidative phosphorylation and ATP generation. This telomere-p53-PGC mitochondrial/ metabolic axis integrates many factors linked to heart aging including increased DNA damage, p53 activation, mitochondrial, and metabolic dysfunction and provides a molecular basis of how dysfunctional telomeres can compromise cardiomyocytes and stem cell compartments in the heart to precipitate cardiac aging. SUMMARY:The aging myocardium with telomere shortening and accumulation of senescent cells restricts the tissue regenerative ability, which contributes to systolic or diastolic heart failure. Moreover, patients with ion-channel defects might have genetic imbalance caused by oxidative stress-related accelerated telomere shortening, which may subsequently cause sudden cardiac death. Telomere length can serve as a marker for the biological status of previous cell divisions and DNA damage with inflammation and oxidative stress. It can be integrated into current risk prediction and stratification models for cardiovascular diseases and can be used in precise personalized treatments. KEYWORDS: aging, telomere, telomerase, aging heart, mitochondria, cardiac stem cell Indones Biomed J. 2017; 9(3): 129-42 Abstract Introduction

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RDoC and translational perspectives on the genetics of trauma‐related psychiatric disorders

Montalvo-Ortiz

Hudziak

Kaufman

2015

American J of Med Genetics Pt B

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Individuals with a history of child abuse are at high risk for depression, anxiety disorders, aggressive behavior, and substance use problems. The goal of this paper is to review studies of the genetics of these stress-related psychiatric disorders. An informative subset of studies that examined candidate gene by environment (GxE) predictors of these psychiatric problems in individuals maltreated as children is reviewed, together with extant genome wide association studies (GWAS). Emerging findings on epigenetic changes associated with adverse early experiences are also reviewed. Meta-analytic support and replicated findings are evident for several genetic risk factors; however, extant research suggests the effects are pleiotropic. Genetic factors are not associated with distinct psychiatric disorders, but rather diverse clinical phenotypes. Research also suggests adverse early life experiences are associated with changes in gene expression of multiple known candidate genes, genes involved in DNA transcription and translation, and genes necessary for brain circuitry development, with changes in gene expression reported in key brain structures implicated in the pathophysiology of psychiatric and substance use disorders. The finding of pleiotropy highlights the value of using the Research Domain Criteria (RDoC) framework in future studies of the genetics of stress-related psychiatric disorders, and not trying simply to link genes to multifaceted clinical syndromes, but to more limited phenotypes that map onto distinct neural circuits. Emerging work in the field of epigenetics also suggests that translational studies that integrate numerous unbiased genome-wide approaches will help to further unravel the genetics of stress-related psychiatric disorders.

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Telomeres, Early-Life Stress and Mental Illness

Cited by 46 publications

References 140 publications

The Cellular Sequelae of Early Stress: Focus on Aging and Mitochondria

The Cellular Sequelae of Early Stress: Focus on Aging and Mitochondria

Telomeres and Telomerase in The Aging Heart

RDoC and translational perspectives on the genetics of trauma‐related psychiatric disorders

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