Telomere Biology and Human Phenotype

Turner, Kara; Vasu, Vimal; Griffin, Darren K.

doi:10.3390/cells8010073

Cited by 242 publications

(232 citation statements)

References 176 publications

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“…DNA polymerase Polα with a single RNA primer initiates the synthesis of a new strand in 5 to 3 direction towards replication fork, which is subsequently replaced by Polε for further elongation, forming the "leading strand" [86,87]. The synthesis of the "lagging strand" in the 5 to 3 direction requires annealing of multiple primers that elongate into short Okazaki fragments opposite to the replication fork and occurs less efficiently than the leading strand [88,89]. On completion of replication, the primer degradation results in internal gaps, filled by the polymerase, Polδ, and ligated to form a continuous strand.…”

Section: Telomere End Replication Problemmentioning

confidence: 99%

“…On completion of replication, the primer degradation results in internal gaps, filled by the polymerase, Polδ, and ligated to form a continuous strand. The gap left by the primer degradation at the terminal end remains unfilled, which results in the loss of a short segment of DNA at the 5 end of the lagging strand [89]. The lagging strand synthesis fails to replicate an average length of~250 nucleotides at the end of linear templates, which is hypothesized due to an inability of DNA Polα-primase to initiate lagging strand synthesis from the very end of linear DNA [90].…”

Section: Telomere End Replication Problemmentioning

confidence: 99%

“…The loss of nucleotides at the chromosomal end leads to the G-rich single strand (Figure 4) at the end of the telomeres and, according to one hypothesis, the size of the 3 overhang is determinant of the rate of telomere shortening [91]. Normal human cells in a culture stop dividing after 40 to 60 passages, a phenomenon first observed by Leonard Hayflick and eponymously called the Hayflick limit [89,92]. Incomplete replication with a gradual shortening of telomeres acts as a counting mechanism that eventually leads to the replicative senescence [93].…”

Section: Telomere End Replication Problemmentioning

confidence: 99%

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Telomeres and Telomere Length: A General Overview

Srinivas

Rachakonda

Kumar

2020

Cancers

176

125

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Telomeres are highly conserved tandem nucleotide repeats that include proximal double-stranded and distal single-stranded regions that in complex with shelterin proteins afford protection at chromosomal ends to maintain genomic integrity. Due to the inherent limitations of DNA replication and telomerase suppression in most somatic cells, telomeres undergo age-dependent incremental attrition. Short or dysfunctional telomeres are recognized as DNA double-stranded breaks, triggering cells to undergo replicative senescence. Telomere shortening, therefore, acts as a counting mechanism that drives replicative senescence by limiting the mitotic potential of cells. Telomere length, a complex hereditary trait, is associated with aging and age-related diseases. Epidemiological data, in general, support an association with varying magnitudes between constitutive telomere length and several disorders, including cancers. Telomere attrition is also influenced by oxidative damage and replicative stress caused by genetic, epigenetic, and environmental factors. Several single nucleotide polymorphisms at different loci, identified through genome-wide association studies, influence inter-individual variation in telomere length. In addition to genetic factors, environmental factors also influence telomere length during growth and development. Telomeres hold potential as biomarkers that reflect the genetic predisposition together with the impact of environmental conditions and as targets for anti-cancer therapies.

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Section: Telomere End Replication Problemmentioning

confidence: 99%

Section: Telomere End Replication Problemmentioning

confidence: 99%

Section: Telomere End Replication Problemmentioning

confidence: 99%

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Telomeres and Telomere Length: A General Overview

Srinivas

Rachakonda

Kumar

2020

Cancers

176

125

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“…This telomere-associated protein complex is composed of six individual factors. The three main components are the telomeric repeat binding factor 1 (TRF1) and 2 (TRF2), that bind to double-stranded telomeric DNA, and the protection of telomeres 1 (POT1), which binds directly to single-stranded telomeric sequences [1][2][3]. These proteins interact with additional factors, such as the TRF1-interacting protein 2 (TIN2), the ACD shelterin complex subunit and telomerase recruitment factor (ACD; formerly known as POT1-and TIN2-organizing protein, TPP1), and the transcriptional repressor/activator protein 1 (TERF2IP, also known as Rap1) [1][2][3].…”

Section: Introductionmentioning

confidence: 99%

The Role of Alternative Lengthening of Telomeres Mechanism in Cancer: Translational and Therapeutic Implications

Recagni

Bidzinska

Zaffaroni

et al. 2020

Cancers

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Telomere maintenance mechanisms (i.e., telomerase activity (TA) and the alternative lengthening of telomere (ALT) mechanism) contribute to tumorigenesis by providing unlimited proliferative capacity to cancer cells. Although the role of either telomere maintenance mechanisms seems to be equivalent in providing a limitless proliferative ability to tumor cells, the contribution of TA and ALT to the clinical outcome of patients may differ prominently. In addition, several strategies have been developed to interfere with TA in cancer, including Imetelstat that has been the first telomerase inhibitor tested in clinical trials. Conversely, the limited information available on the molecular underpinnings of ALT has hindered thus far the development of genuine ALT-targeting agents. Moreover, whether anti-telomerase therapies may be hampered or not by possible adaptive responses is still debatable. Nonetheless, it is plausible hypothesizing that treatment with telomerase inhibitors may exert selective pressure for the emergence of cancer cells that become resistant to treatment by activating the ALT mechanism. This notion, together with the evidence that both telomere maintenance mechanisms may coexist within the same tumor and may distinctly impinge on patients’ outcomes, suggests that ALT may exert an unexpected role in tumor biology that still needs to be fully elucidated.

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“…Telomere. Telomeres, composed of the telomere DNA sequence and telomere protein, are nucleoprotein structures located at the end of chromosomes, which control the cell division cycle and maintain the genome's integrity [83].…”

Section: Vascular Smooth Muscle Cellsmentioning

confidence: 99%

New Insights for Cellular and Molecular Mechanisms of Aging and Aging-Related Diseases: Herbal Medicine as Potential Therapeutic Approach

Liu

Wei-liang

Gao

et al. 2019

Oxidative Medicine and Cellular Longevity

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Aging is a progressive disease affecting around 900 million people worldwide, and in recent years, the mechanism of aging and aging-related diseases has been well studied. Treatments for aging-related diseases have also made progress. For the long-term treatment of aging-related diseases, herbal medicine is particularly suitable for drug discovery. In this review, we discuss cellular and molecular mechanisms of aging and aging-related diseases, including oxidative stress, inflammatory response, autophagy and exosome interactions, mitochondrial injury, and telomerase damage, and summarize commonly used herbals and compounds concerned with the development of aging-related diseases, including Ginkgo biloba, ginseng, Panax notoginseng, Radix astragali, Lycium barbarum, Rhodiola rosea, Angelica sinensis, Ligusticum chuanxiong, resveratrol, curcumin, and flavonoids. We also summarize key randomized controlled trials of herbal medicine for aging-related diseases during the past ten years. Adverse reactions of herbs were also described. It is expected to provide new insights for slowing aging and treating aging-related diseases with herbal medicine.

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Telomere Biology and Human Phenotype

Cited by 242 publications

References 176 publications

Telomeres and Telomere Length: A General Overview

Telomeres and Telomere Length: A General Overview

The Role of Alternative Lengthening of Telomeres Mechanism in Cancer: Translational and Therapeutic Implications

New Insights for Cellular and Molecular Mechanisms of Aging and Aging-Related Diseases: Herbal Medicine as Potential Therapeutic Approach

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