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They "cap" the end-sequences and are progressively degraded in the process of DNA replication. The "end replication problem" is exclusive to linear chromosomes as circular chromosomes do not have ends lying without reach of DNA-polymerases. Most prokaryotes, relying on circular chromosomes, accordingly do not possess telomeres. [12]
This is known as the end replication problem. [1] The end replication problem is handled in eukaryotic cells by telomere regions and telomerase. Telomeres extend the 3' end of the parental chromosome beyond the 5' end of the daughter strand. This single-stranded DNA structure can act as an origin of replication that recruits telomerase.
Eukaryotes initiate DNA replication at multiple points in the chromosome, so replication forks meet and terminate at many points in the chromosome. Because eukaryotes have linear chromosomes, DNA replication is unable to reach the very end of the chromosomes. Due to this problem, DNA is lost in each replication cycle from the end of the chromosome.
This is known as the "end replication problem". [16] Olovnikov proposed that every time a cell divides, a part of the DNA sequence is lost, and if this loss reaches a certain level, cell division will stop at the end.
This problem makes eukaryotic cells unable to copy the last few bases on the 3' end of the template DNA strand, leading to chromosome—and, therefore, telomere—shortening every S phase. [2] Measurements of telomere lengths across cell types at various ages suggest that this gradual chromosome shortening results in a gradual reduction in ...
In an organism with a very large genome, circular chromosomes could potentially cause problems relating to torsional strain. [citation needed] Linear chromosomes are also in some ways disadvantageous or problematic, one of the biggest potential issues being the end replication problem. This is a phenomenon which occurs due to the directionality ...
During telomeric DNA replication in the S/G2 and G1 phases of the cell cycle, the 3' lagging strand leaves a short overhang called a G-tail. [4] [3] Telomeric DNA ends at the 3' G tail end because the 3' lagging strand extends without its complementary 5' C leading strand. The G tail provide a major function to telomeric DNA such that the G ...
This is sometimes called the "end replication problem". If a cell did not contain telomeres, genetic information from the DNA on the ends of chromosomes would be lost with each division. However, because chromosomes have telomeres or mega-telomeres on their ends, repetitive non-essential sequences of DNA are lost instead (See: Telomere shortening).