Difference between revisions of "Addition of Telomerase to Somatic Cells"
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Telomeres are undoubtedly essential resources in the process of DNA replication. Telomerase has the potential to increase the supply of that resource infinitely. It is therefore imperative to study telomerase much more. This will require an approach that studies the structure in various species. This is to prove or disprove its impact on the aging of organisms. If telomerase is to be ever used in any anti-aging therapy then it would require further insight into its relationship with cancer otherwise it would be counterintuitive. Some <br><i>Hydra vulgaris </i> are non-aging and hence could be used as a model organism to study this phenomenon.
Telomeres are undoubtedly essential resources in the process of DNA replication. Telomerase has the potential to increase the supply of that resource infinitely. It is therefore imperative to study telomerase much more. This will require an approach that studies the structure in various species. This is to prove or disprove its impact on the aging of organisms. If telomerase is to be ever used in any anti-aging therapy then it would require further insight into its relationship with cancer otherwise it would be counterintuitive. Some<br><i>Hydra vulgaris </i> are non-aging and hence could be used as a model organism to study this phenomenon.
Revision as of 02:35, 7 December 2019
Telomerase is an enzyme that is able to regenerate telomeres. In humans, it is found in some tissues, such as male germ cells, activated lymphocytes, and certain types of stem cell populations. If present in somatic cells, it can turn them cancerous. Telomere shortening can be one of the factors which contribute to aging so it is worthwhile to look into such an addition to develop anti-aging treatments.
Telomerase is a reverse transcriptase enzyme with its own RNA template. This makes it very similar to retroviruses with the notable exception of capsids. Endogenous retroviruses (ERVs) are endogenous viral elements in the genome that closely resemble and can be derived from retroviruses. They are abundant in the genomes of jawed vertebrates, and they comprise up to 5–8% of the human genome (lower estimates of ~1%). Such similarities could be used to establish the idea that viruses may have fused with the cells of other organisms to give rise to telomerase in the course of evolution from the RNA world. 
Telomeres are repeating sequences of nucleotides at the end of chromosomes which do not code for any proteins. This sequence has been identified to be "TTAGGC". Now, DNA polymerase is not capable of replicating the chromosome along its entire length. Hence every time DNA replications are undergone, the ends of chromosomes will be left out. Telomeres are extra sequences at those very ends so they can be lost instead of other vital protein-coding sequences. Leonard Hayflick demonstrated that a normal human fetal cell population will divide between 40 and 60 times in cell culture before entering a senescence phase. It occurs because each time a cell undergoes mitosis, the telomeres on the ends of each chromosome shorten slightly. Cell division will cease once telomeres shorten to a critical length. Hayflick interpreted his discovery to be aging at the cellular level.
The molecular composition of the human telomerase complex was determined by Scott Cohen and his team at the Children's Medical Research Institute (Sydney Australia) and consists of two molecules each of human telomerase reverse transcriptase (TERT), telomerase RNA (TR or TERC), and dyskerin (DKC1). That was the whole complex but the parts of telomerase of key interest: one is the functional RNA component, hTERC which serves as a template for telomeric DNA synthesis: the other is a catalytic protein, hTERT with reverse transcriptase activity .The genes of telomerase subunits, which include TERT, TERC, DKC1 and TEP1, are located on different chromosomes. The human TERT gene (hTERT) is translated into a protein of 1132 amino acids. TERT polypeptide folds with (and carries) TERC, a non-coding RNA (451 nucleotides long).
Telomerase Gene in Human Somatic Cells
Among the core components of human telomerase, only the catalytic component hTERT seems to be the limiting determinant of telomerase activity, as other components are undergo constitutive regulation. Substantial experimental data demonstrate that the transcriptional regulation of hTERT expression represents the primary and rate-limiting step in the activation of telomerase activity in most cells. It has been proposed that the lack of telomerase activity in most somatic human cells is due to transcriptional repression of the hTERT gene. Consistent with this hypothesis, cell fusions between normal somatic cells and some telomerase-positive immortal cells result in repression of telomerase activity . Importantly, microcell-mediated transfer of specific human chromosomes into cancer cells results in repression of hTERT expression and downregulation of telomerase activity . These observations indicate that normal cells express functional transcriptional repressors of hTERT .
Telomerase Activity in Human Somatic Cells
Most types of normal human somatic cells, however, are telomerase negative and have a limited replicative capacity . When this limit is reached, which depends on cell type and origin, cells will permanently stop dividing. It has been suggested that senescence could function as a tumor suppressor mechanism to prevent the accumulation of multiple oncogenic mutations . Telomerase activity was found to be absent in most normal human somatic cells but present in over 90% of cancerous cells and in vitro-immortalized cells  Hence loss of TERT repressors results in the upregulation of hTERT expression and telomerase activity seen during multistage carcinogenesis and associated with cellular immortality.
Telomerase Activity in Other Species
The presence of the enzyme telomerase reverse transcriptase (TERT) can stop the telomere shortening that results from cell division by elongating the repetitive sequences within the telomere, which theoretically leads to unlimited replicative capacity. On the other hand, continuous telomere-shortening might limit the ability to repair damaged cells, which, according to the telomere theory of aging, is believed to be the main reason why organisms are debilitated in later age and finally show an age-related increase in mortality. However, in the nonaging Hydra species, telomere dynamics remain poorly understood. Indirect proof of a possible telomerase activity in Hydra and a prerequisite for constant cell proliferation and regeneration has been deduced from the presence of a gene-encoding TERT, as identified in the genome of H. magnipapillata.  Other species characterized by a high level of cell proliferation, such as sponges, preserve telomere integrity via a high telomerase activity. Many invertebrates, fish, amphibians, and reptiles that show continuous cell proliferation to maintain a high regeneration ability require high telomerase activities . These observations suggest that the clonal lineages of Hydra, with a stable cell proliferation rate, might preserve their long-term telomere integrity via telomerase activity.
Telomeres are undoubtedly essential resources in the process of DNA replication. Telomerase has the potential to increase the supply of that resource infinitely. It is therefore imperative to study telomerase much more. This will require an approach that studies the structure in various species. This is to prove or disprove its impact on the aging of organisms. If telomerase is to be ever used in any anti-aging therapy then it would require further insight into its relationship with cancer otherwise it would be counterintuitive. Some
Hydra vulgaris are non-aging and hence could be used as a model organism to study this phenomenon.