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The core domain and CR4/CR5 conserved domain associate with TERT, and are the only domains of TERC necessary for in vitro catalytic activity of telomerase. [11] The 3’ end of TERC consists of a conserved H/ACA domain, [10] a 2 hairpin structure connected by a single-stranded hinge and bordered on the 3’ end by a single-stranded ACA sequence ...
The genes of telomerase subunits, which include TERT, [16] TERC, [17] DKC1 [18] and TEP1, [19] are located on different chromosomes. The human TERT gene (hTERT) is translated into a protein of 1132 amino acids. [20] TERT polypeptide folds with (and carries) TERC, a non-coding RNA (451 nucleotides long). TERT has a 'mitten' structure that allows ...
[23] [24] These structures form due to the abundance of guanine found in the TERRA transcript and their ability to associate through Hoogsteen hydrogen bonding. The resulting square planar structure is known as a guanine tetrad (also known as a G-tetrad or G-quartet) and when two or more guanine tetrads stack on top of each other, they form a G ...
Telomerase reverse transcriptase (abbreviated to TERT, or hTERT in humans) is a catalytic subunit of the enzyme telomerase, which, together with the telomerase RNA component (TERC), comprises the most important unit of the telomerase complex. [5] [6] Telomerases are part of a distinct subgroup of RNA-dependent polymerases.
A small fraction of bacterial chromosomes (such as those in Streptomyces, Agrobacterium, and Borrelia), however, are linear and possess telomeres, which are very different from those of the eukaryotic chromosomes in structure and function. The known structures of bacterial telomeres take the form of proteins bound to the ends of linear ...
Shelterin (also called telosome) is a protein complex known to protect telomeres in many eukaryotes from DNA repair mechanisms, as well as to regulate telomerase activity. In mammals and other vertebrates, telomeric DNA consists of repeating double-stranded 5'-TTAGGG-3' (G-strand) sequences (2-15 kilobases in humans) along with the 3'-AATCCC-5' (C-strand) complement, ending with a 50-400 ...
Equivalent genes were later found in Arabidopsis, [29] where they are also involved in controlling the development of carpels and the ovule and even with structures related to seed dispersal. The appearance of interesting phenotypes in RNA interference studies in Petunia and tomato led, in 1994, to the definition of a new type of function in ...
To date, at least 14 different helicases have been isolated from single celled organisms, 6 helicases from bacteriophages, 12 from viruses, 15 from yeast, 8 from plants, 11 from calf thymus, and approximately 25 helicases from human cells. [16] Below is a history of helicase discovery: 1976 – Discovery and isolation of E. coli-based DNA ...