Tandem repeat

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In genetics, tandem repeats occur in DNA when a pattern of one or more nucleotides is repeated and the repetitions are directly adjacent to each other, e.g. ATTCG ATTCG ATTCG, in which the sequence ATTCG is repeated three times.[1]

Several protein domains also form tandem repeats within their amino acid primary structure, such as armadillo repeats. However, in proteins, perfect tandem repeats are rare in naturally proteins, but they have been added to designed proteins.[2]

Tandem repeats constitute about 8% of the human genome.[3] They are implicated in more than 50 lethal human diseases, including amyotrophic lateral sclerosis, Huntington's disease, and several cancers.[4]

Terminology

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All tandem repeat arrays are classifiable as satellite DNA, a name originating from the fact that tandem DNA repeats, by nature of repeating the same nucleotide sequences repeatedly, have a unique ratio of the two possible nucleotide base pair combinations, conferring them a specific mass density that allows them to be separated from the rest of the genome with density-based laboratory techniques, thus appearing as "satellite bands". Albeit, a tandem repeat array could not show up as a satellite band if it had a nucleotide composition close to the average of the genome.[citation needed]

When exactly two nucleotides are repeated, it is called a dinucleotide repeat (for example: ACACACAC...). The microsatellite instability in hereditary nonpolyposis colon cancer most commonly affects such regions.[5]

When three nucleotides are repeated, it is called a trinucleotide repeat (for example: CAGCAGCAGCAG...), and abnormalities in such regions can give rise to trinucleotide repeat disorders.

When between 10 and 60 nucleotides are repeated, it is called a minisatellite. Those with fewer are known as microsatellites or short tandem repeats.

When much larger lengths of nucleotides are repeated, on the order of 1,000 nucleotides, it is called a macrosatellite.

When the repeat unit copy number is variable in the population being considered, it is called a variable number tandem repeat (VNTR). MeSH classifies variable number tandem repeats under minisatellites.[6]

Mechanism

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Tandem repeats can occur through different mechanisms. For example, slipped strand mispairing, (also known as replication slippage), is a mutation process which occurs during DNA replication. It involves denaturation and displacement of the DNA strands, resulting in mispairing of the complementary bases. Slipped strand mispairing is one explanation for the origin and evolution of repetitive DNA sequences.

Other mechanisms include unequal crossover and gene conversion.

Uses

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Tandem repeat describes a pattern that helps determine an individual's inherited traits.

Tandem repeats can be very useful in determining parentage. Short tandem repeats are used for certain genealogical DNA tests. DNA is examined from microsatellites within the chromosomal DNA. Parentage can be determined through the similarity in these regions.

Polymorphic tandem repeats (alias VNTRs) are also present in microorganisms and can be used to trace the origin of an outbreak. The corresponding assay in which a collection of VNTRs is typed to characterize a strain is most often called MLVA (Multiple Loci VNTR Analysis). Using tandem repeat polymorphism, recombination has been reported in the natural transmission of monkeypox (mpox) virus genome during 2022 pandemic.[7]

In the field of computer science, tandem repeats in strings (e.g., DNA sequences) can be efficiently detected using suffix trees or suffix arrays.

Studies in 2004 linked the unusual genetic plasticity of dogs to mutations in tandem repeats.[8]

Nested tandem repeats are described as repeating unit lengths that are variable or unknown and frequently include an asymmetric hierarchy of smaller repeating units. These repeats are constructed from distinct groups of homologous-length monomers. An algorithm known as NTRprism was created by Oxford Nanopore Technologies researchers to enable for the annotation of repetitive structures in built satellite DNA arrays. The algorithm NTRprism is developed to find and display the satellite repeating periodicity.[9]

See also

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References

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  1. ^ Tandem Repeat at the U.S. National Library of Medicine Medical Subject Headings (MeSH)
  2. ^ Jorda J, Xue B, Uversky VN, Kajava AV (June 2010). "Protein tandem repeats - the more perfect, the less structured". The FEBS Journal. 277 (12): 2673–82. doi:10.1111/j.1742-4658.2010.07684.x. PMC 2928880. PMID 20553501.
  3. ^ Duitama J, Zablotskaya A, Gemayel R, Jansen A, Belet S, Vermeesch JR, Verstrepen KJ, Froyen G (May 2014). "Large-scale analysis of tandem repeat variability in the human genome". Nucleic Acids Research. 42 (9): 5728–5741. doi:10.1093/nar/gku212. PMC 4027155. PMID 24682812.
  4. ^ Cui, Ya; Ye, Wenbin; Li, Jason Sheng; Li, Jingyi Jessica; Vilain, Eric; Sallam, Tamer; Li, Wei (April 2024). "A genome-wide spectrum of tandem repeat expansions in 338,963 humans". Cell. 187 (9): 2336–2341.e5. doi:10.1016/j.cell.2024.03.004. ISSN 0092-8674.
  5. ^ Oki E, Oda S, Maehara Y, Sugimachi K (March 1999). "Mutated gene-specific phenotypes of dinucleotide repeat instability in human colorectal carcinoma cell lines deficient in DNA mismatch repair". Oncogene. 18 (12): 2143–7. doi:10.1038/sj.onc.1202583. PMID 10321739.
  6. ^ Variable Number of Tandem Repeats at the U.S. National Library of Medicine Medical Subject Headings (MeSH)
  7. ^ Yeh, Ting-Yu; Hsieh, Zih-Yu; Feehley, Michael C.; Feehley, Patrick J.; Contreras, Gregory P.; Su, Ying-Chieh; Hsieh, Shang-Lin; Lewis, Dylan A. (9 December 2022). "Recombination shapes the 2022 monkeypox (mpox) outbreak". Med. 3 (12): 824–826. doi:10.1016/j.medj.2022.11.003. ISSN 2666-6359. PMC 9733179. PMID 36495863.
  8. ^ Pennisi E (December 2004). "Genetics. A ruff theory of evolution: gene stutters drive dog shape". Science. 306 (5705): 2172. doi:10.1126/science.306.5705.2172. PMID 15618495. S2CID 10680162.
  9. ^ Altemose, Nicolas; Logsdon, Glennis A.; Bzikadze, Andrey V.; Sidhwani, Pragya; Langley, Sasha A.; Caldas, Gina V.; Hoyt, Savannah J.; Uralsky, Lev; Ryabov, Fedor D.; Shew, Colin J.; Sauria, Michael E. G.; Borchers, Matthew; Gershman, Ariel; Mikheenko, Alla; Shepelev, Valery A. (April 2022). "Complete genomic and epigenetic maps of human centromeres". Science. 376 (6588): eabl4178. doi:10.1126/science.abl4178. ISSN 0036-8075. PMC 9233505. PMID 35357911.
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