Telomeres are protective structures, composed of nucleic acids and a complex protein mixture, located at the end of the chromosomes. They play an important role in preventing genomic instability and ensuring cell health. Defects in telomere integrity result in cell dysfunction and the development of diseases, including neurodegenerative disorders, cancer and premature aging syndromes, among others. Loss of telomere integrity during normal cell aging also initiates DNA damage signals that culminate in the senescence phenotype. Fluorescence microscopy has allowed researchers to study the dynamics, shape, localization, and co-distribution of telomeres with proteins of interest. The microscopy tools to investigate these structures have evolved, making it possible to understand in greater detail the molecular mechanisms affecting telomeres that contribute to cell aging and the development of age-related diseases. Using human fibroblasts as an example, we will highlight several characteristics of telomeres that can be investigated using three different microscopy systems, including wide-field microscopy, and the two super-resolution techniques called 3D Structured Illumination Microscopy (3D-SIM) and direct Stochastic Optical Reconstruction Microscopy (dSTORM). In this review, we will also discuss their limitations and highlight their importance in answering telomere-related scientific questions.
Keywords: Fluorescence microscopy; Senescence; Super-resolution microscopy; Telomere biology.
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