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Retrotransposon

January 31, 2023

Retrotransposons (also called Class I transposable elements or transposons via RNA intermediates) are a type of genetic component that copy and paste themselves into different genomic locations (transposon) by converting RNA back into DNA through the reverse transcription process using an RNA transposition intermediate.[1]

Simplified representation of the life cycle of a retrotransposon

Through reverse transcription, retrotransposons amplify themselves quickly to become abundant in eukaryotic genomes such as maize (49–78%)[2] and humans (42%).[3] They are only present in eukaryotes but share features with retroviruses such as HIV, for example, discontinuous reverse transcriptase-mediated extrachromosomal recombination.[4][5]

These retrotransposons are regulated by a family of short non-coding RNAs termed as PIWI [P-element induced wimpy testis]-interacting RNAs (piRNAs).[6] piRNA is a recently discovered class of ncRNAs, which are in the length range of ~24-32 nucleotides. Initially, piRNAs were described as repeat-associated siRNAs (rasiRNAs) because of their origin from the repetitive elements such as transposable sequences of the genome. However, later it was identified that they acted via PIWI-protein. In addition to having a role in the suppression of genomic transposons, various roles of piRNAs have been recently reported like regulation of 3’ UTR of protein-coding genes via RNAi, transgenerational epigenetic inheritance to convey a memory of past transposon activity, and RNA-induced epigenetic silencing.[6]

There are two main types of retrotransposons, long terminal repeats (LTRs) and non-long terminal repeats (non-LTRs). Retrotransposons are classified based on sequence and method of transposition.[7] Most retrotransposons in the maize genome are LTR, whereas in humans they are mostly non-LTR. Retrotransposons (mostly of the LTR type) can be passed onto the next generation of a host species through the germline.

The other type of transposon is the DNA transposon. DNA transposons encode a transposase which, when translated, catalyses the excision of the transposase gene and its flanking region and its insertion into a different genomic location: a 'jumping' DNA element.[8] Hence retrotransposons can be thought of as replicative, whereas DNA transposons are non-replicative. Due to their replicative nature, retrotransposons can increase eukaryotic genome size quickly and survive in eukaryotic genomes permanently. It is thought that staying in eukaryotic genomes for such long periods gave rise to special insertion methods that do not affect eukaryotic gene function drastically.[9]

LTR retrotransposons

Main article: LTR retrotransposon

Long strands of repetitive DNA can be found at each end of a LTR retrotransposon. These are termed long terminal repeats (LTRs) that are each a few hundred base pairs long, hence retrotransposons with LTRs have the name long terminal repeat (LTR) retrotransposon. LTR retrotransposons are over 5 kilobases long. Between the long terminal repeats there are genes that can be transcribed equivalent to retrovirus genes gag and pol. These genes overlap so they encode a protease that processes the resulting transcript into functional gene products. Gag gene products associate with other retrotransposon transcripts to form virus-like particles. Pol gene products include enzymes reverse transcriptase, integrase and ribonuclease H domains. Reverse transcriptase carries out reverse transcription of retrotransposon DNA. Integrase 'integrates' retrotransposon DNA into eukaryotic genome DNA. Ribonuclease cleaves phosphodiester bonds between RNA nucleotides.

LTR retrotransposons encode transcripts with tRNA binding sites so that they can undergo reverse transcription. The tRNA-bound RNA transcript binds to a genomic RNA sequence. Template strand of retrotransposon DNA can hence be synthesised. Ribonuclease H domains degrade eukaryotic genomic RNA to give adenine- and guanine-rich DNA sequences that flag where the complementary noncoding strand has to be synthesised. Integrase then 'integrates' the retrotransposon into eukaryotic DNA using the hydroxyl group at the start of retrotransposon DNA. This results in a retrotransposon flagged by long terminal repeats at its ends. Because the retrotransposon contains eukaryotic genome information it can insert copies of itself into other genomic locations within a eukaryotic cell.

Endogenous retrovirus

Main article: Endogenous retrovirus

An endogenous retrovirus is a retrovirus without virus pathogenic effects that has been integrated into the host genome by inserting their inheritable genetic information into cells that can be passed onto the next generation like a retrotransposon.[10] Because of this, they share features with retroviruses and retrotransposons. When the retroviral DNA is integrated into the host genome they evolve into endogenous retroviruses that influence eukaryotic genomes. So many endogenous retroviruses have inserted themselves into eukaryotic genomes that they allow insight into biology between viral-host interactions and the role of retrotransposons in evolution and disease. Many retrotransposons share features with endogenous retroviruses, the property of recognising and fusing with the host genome. However, there is a key difference between retroviruses and retrotransposons, which is indicated by the env gene. Although similar to the gene carrying out the same function in retroviruses, the env gene is used to determine whether the gene is retroviral or retrotransposon. If the gene is retroviral it can evolve from a retrotransposon into a retrovirus. They differ by the order of sequences in pol genes. Env genes are found in LTR retrotransposon types Ty1-copia (Pseudoviridae), Ty3-gypsy (Metaviridae) and BEL/Pao.[11][10] They encode glycoproteins on the retrovirus envelope needed for entry into the host cell. Retroviruses can move between cells whereas LTR retrotransposons can only move themselves into the genome of the same cell.[12] Many vertebrate genes were formed from retroviruses and LTR retrotransposons. One endogenous retrovirus or LTR retrotransposon has the same function and genomic locations in different species, suggesting their role in evolution.[13]

Non-LTR retrotransposons

Like LTR retrotransposons, non-LTR retrotransposons contain genes for reverse transcriptase, RNA-binding protein, nuclease, and sometimes ribonuclease H domain[14] but they lack the long terminal repeats. RNA-binding proteins bind the RNA-transposition intermediate and nucleases are enzymes that break phosphodiester bonds between nucleotides in nucleic acids. Instead of LTRs, non-LTR retrotransposons have short repeats that can have an inverted order of bases next to each other aside from direct repeats found in LTR retrotransposons that is just one sequence of bases repeating itself.

Although they are retrotransposons, they cannot carry out reverse transcription using an RNA transposition intermediate in the same way as LTR retrotransposons. Those two key components of the retrotransposon are still necessary but the way they are incorporated into the chemical reactions is different. This is because unlike LTR retrotransposons, non-LTR retrotransposons do not contain sequences that bind tRNA.

They mostly fall into two types – LINEs and SINEs. SVA elements are the exception between the two as they share similarities with both LINEs and SINEs, containing Alu elements and different numbers of the same repeat. SVAs are shorter than LINEs but longer than SINEs.

While historically viewed as "junk DNA", research suggests in some cases, both LINEs and SINEs were incorporated into novel genes to form new functions.[15]

LINEs

Main article: Long interspersed nuclear element

When a LINE is transcribed, the transcript contains an RNA polymerase II promoter that ensures LINEs can be copied into whichever location it inserts itself into. RNA polymerase II is the enzyme that transcribes genes into mRNA transcripts. The ends of LINE transcripts are rich in multiple adenines,[16] the bases that are added at the end of transcription so that LINE transcripts would not be degraded. This transcript is the RNA transposition intermediate.

The RNA transposition intermediate moves from the nucleus into the cytoplasm for translation. This gives the two coding regions of a LINE that in turn binds back to the RNA it is transcribed from. The LINE RNA then moves back into the nucleus to insert into the eukaryotic genome.

LINEs insert themselves into regions of the eukaryotic genome that are rich in bases AT. At AT regions LINE uses its nuclease to cut one strand of the eukaryotic double-stranded DNA. The adenine-rich sequence in LINE transcript base pairs with the cut strand to flag where the LINE will be inserted with hydroxyl groups. Reverse transcriptase recognises these hydroxyl groups to synthesise LINE retrotransposon where the DNA is cut. Like with LTR retrotransposons, this new inserted LINE contains eukaryotic genome information so it can be copied and pasted into other genomic regions easily. The information sequences are longer and more variable than those in LTR retrotransposons.

Most LINE copies have variable length at the start because reverse transcription usually stops before DNA synthesis is complete. In some cases this causes RNA polymerase II promoter to be lost so LINEs cannot transpose further.[17]

 
Genetic structure of murine LINE1 and SINEs. Bottom: proposed structure of L1 RNA-protein (RNP) complexes. ORF1 proteins form trimers, exhibiting RNA binding and nucleic acid chaperone activity.[18]

Human L1

Main article: LINE1

LINE-1 (L1) retrotransposons make up a significant portion of the human genome, with an estimated 500,000 copies per genome. Genes encoding for human LINE1 usually have their transcription inhibited by methyl groups binding to its DNA carried out by PIWI proteins and enzymes DNA methyltransferases. L1 retrotransposition can disrupt the nature of genes transcribed by pasting themselves inside or near genes which could in turn lead to human disease. LINE1s can only retrotranspose in some cases to form different chromosome structures contributing to differences in genetics between individuals.[19] There is an estimate of 80–100 active L1s in the reference genome of the Human Genome Project, and an even smaller number of L1s within those active L1s retrotranspose often. L1 insertions have been associated with tumorigenesis by activating cancer-related genes oncogenes and diminishing tumor suppressor genes.

Each human LINE1 contains two regions from which gene products can be encoded. The first coding region contains a leucine zipper protein involved in protein-protein interactions and a protein that binds to the terminus of nucleic acids. The second coding region has a purine/pyrimidine nuclease, reverse transcriptase and protein rich in amino acids cysteines and histidines. The end of the human LINE1, as with other retrotransposons is adenine-rich.[20][21][22]

SINEs

Main article: Short interspersed nuclear element

SINEs are much shorter (300bp) than LINEs.[23] They share similarity with genes transcribed by RNA polymerase II, the enzyme that transcribes genes into mRNA transcripts, and the initiation sequence of RNA polymerase III, the enzyme that transcribes genes into ribosomal RNA, tRNA and other small RNA molecules.[24] SINEs such as mammalian MIR elements have tRNA gene at the start and adenine-rich at the end like in LINEs.

SINEs do not encode a functional reverse transcriptase protein and rely on other mobile transposons, especially LINEs.[25] SINEs exploit LINE transposition components despite LINE-binding proteins prefer binding to LINE RNA. SINEs cannot transpose by themselves because they cannot encode SINE transcripts. They usually consist of parts derived from tRNA and LINEs. The tRNA portion contains an RNA polymerase III promoter which the same kind of enzyme as RNA polymerase II. This makes sure the LINE copies would be transcribed into RNA for further transposition. The LINE component remains so LINE-binding proteins can recognise the LINE part of the SINE.

Alu elements

Main article: Alu element

Alus are the most common SINE in primates. They are approximately 350 base pairs long, do not encode proteins and can be recognized by the restriction enzyme AluI (hence the name). Their distribution may be important in some genetic diseases and cancers. Copy and pasting Alu RNA requires the Alu's adenine-rich end and the rest of the sequence bound to a signal. The signal-bound Alu can then associate with ribosomes. LINE RNA associates on the same ribosomes as the Alu. Binding to the same ribosome allows Alus of SINEs to interact with LINE. This simultaneous translation of Alu element and LINE allows SINE copy and pasting.

SVA elements

SVA elements are present at lower levels than SINES and LINEs in humans. The starts of SVA and Alu elements are similar, followed by repeats and an end similar to endogenous retrovirus. LINEs bind to sites flanking SVA elements to transpose them. SVA are one of the youngest transposons in great apes genome and among the most active and polymorphic in the human population.

Role in human disease

Retrotransposons ensure they are not lost by chance by occurring only in cell genetics that can be passed on from one generation to the next from parent gametes. However, LINEs can transpose into the human embryo cells that eventually develop into the nervous system, raising the question whether this LINE retrotransposition affects brain function. LINE retrotransposition is also a feature of several cancers, but it is unclear whether retrotransposition itself causes cancer instead of just a symptom. Uncontrolled retrotransposition is bad for both the host organism and retrotransposons themselves so they have to be regulated. Retrotransposons are regulated by RNA interference. RNA interference is carried out by a bunch of short non-coding RNAs. The short non-coding RNA interacts with protein Argonaute to degrade retrotransposon transcripts and change their DNA histone structure to reduce their transcription.

Role in evolution

LTR retrotransposons came about later than non-LTR retrotransposons, possibly from an ancestral non-LTR retrotransposon acquiring an integrase from a DNA transposon. Retroviruses gained additional properties to their virus envelopes by taking the relevant genes from other viruses using the power of LTR retrotransposon.

Due to their retrotransposition mechanism, retrotransposons amplify in number quickly, composing 40% of the human genome. The insertion rates for LINE1, Alu and SVA elements are 1/200 – 1/20, 1/20 and 1/900 respectively. The LINE1 insertion rates have varied a lot over the past 35 million years, so they indicate points in genome evolution.

Notably a large number of 100 kilobases in the maize genome show variety due to the presence or absence of retrotransposons. However since maize is unusual genetically as compared to other plants it cannot be used to predict retrotransposition in other plants.

Mutations caused by retrotransposons include:

  • Gene inactivation
  • Changing gene regulation
  • Changing gene products
  • Acting as DNA repair sites

Role in biotechnology

See also

References

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  25. ^ Dewannieux M, Esnault C, Heidmann T (September 2003). "LINE-mediated retrotransposition of marked Alu sequences". Nature Genetics. 35 (1): 41–8. doi:10.1038/ng1223. PMID 12897783. S2CID 32151696.

January 31, 2023
retrotransposon, also, called, class, transposable, elements, transposons, intermediates, type, genetic, component, that, copy, paste, themselves, into, different, genomic, locations, transposon, converting, back, into, through, reverse, transcription, process. Retrotransposons also called Class I transposable elements or transposons via RNA intermediates are a type of genetic component that copy and paste themselves into different genomic locations transposon by converting RNA back into DNA through the reverse transcription process using an RNA transposition intermediate 1 Simplified representation of the life cycle of a retrotransposon Through reverse transcription retrotransposons amplify themselves quickly to become abundant in eukaryotic genomes such as maize 49 78 2 and humans 42 3 They are only present in eukaryotes but share features with retroviruses such as HIV for example discontinuous reverse transcriptase mediated extrachromosomal recombination 4 5 These retrotransposons are regulated by a family of short non coding RNAs termed as PIWI P element induced wimpy testis interacting RNAs piRNAs 6 piRNA is a recently discovered class of ncRNAs which are in the length range of 24 32 nucleotides Initially piRNAs were described as repeat associated siRNAs rasiRNAs because of their origin from the repetitive elements such as transposable sequences of the genome However later it was identified that they acted via PIWI protein In addition to having a role in the suppression of genomic transposons various roles of piRNAs have been recently reported like regulation of 3 UTR of protein coding genes via RNAi transgenerational epigenetic inheritance to convey a memory of past transposon activity and RNA induced epigenetic silencing 6 There are two main types of retrotransposons long terminal repeats LTRs and non long terminal repeats non LTRs Retrotransposons are classified based on sequence and method of transposition 7 Most retrotransposons in the maize genome are LTR whereas in humans they are mostly non LTR Retrotransposons mostly of the LTR type can be passed onto the next generation of a host species through the germline The other type of transposon is the DNA transposon DNA transposons encode a transposase which when translated catalyses the excision of the transposase gene and its flanking region and its insertion into a different genomic location a jumping DNA element 8 Hence retrotransposons can be thought of as replicative whereas DNA transposons are non replicative Due to their replicative nature retrotransposons can increase eukaryotic genome size quickly and survive in eukaryotic genomes permanently It is thought that staying in eukaryotic genomes for such long periods gave rise to special insertion methods that do not affect eukaryotic gene function drastically 9 Contents 1 LTR retrotransposons 2 Endogenous retrovirus 3 Non LTR retrotransposons 3 1 LINEs 3 1 1 Human L1 3 2 SINEs 3 2 1 Alu elements 4 SVA elements 5 Role in human disease 6 Role in evolution 7 Role in biotechnology 8 See also 9 ReferencesLTR retrotransposons EditMain article LTR retrotransposon Long strands of repetitive DNA can be found at each end of a LTR retrotransposon These are termed long terminal repeats LTRs that are each a few hundred base pairs long hence retrotransposons with LTRs have the name long terminal repeat LTR retrotransposon LTR retrotransposons are over 5 kilobases long Between the long terminal repeats there are genes that can be transcribed equivalent to retrovirus genes gag and pol These genes overlap so they encode a protease that processes the resulting transcript into functional gene products Gag gene products associate with other retrotransposon transcripts to form virus like particles Pol gene products include enzymes reverse transcriptase integrase and ribonuclease H domains Reverse transcriptase carries out reverse transcription of retrotransposon DNA Integrase integrates retrotransposon DNA into eukaryotic genome DNA Ribonuclease cleaves phosphodiester bonds between RNA nucleotides LTR retrotransposons encode transcripts with tRNA binding sites so that they can undergo reverse transcription The tRNA bound RNA transcript binds to a genomic RNA sequence Template strand of retrotransposon DNA can hence be synthesised Ribonuclease H domains degrade eukaryotic genomic RNA to give adenine and guanine rich DNA sequences that flag where the complementary noncoding strand has to be synthesised Integrase then integrates the retrotransposon into eukaryotic DNA using the hydroxyl group at the start of retrotransposon DNA This results in a retrotransposon flagged by long terminal repeats at its ends Because the retrotransposon contains eukaryotic genome information it can insert copies of itself into other genomic locations within a eukaryotic cell Endogenous retrovirus EditMain article Endogenous retrovirus An endogenous retrovirus is a retrovirus without virus pathogenic effects that has been integrated into the host genome by inserting their inheritable genetic information into cells that can be passed onto the next generation like a retrotransposon 10 Because of this they share features with retroviruses and retrotransposons When the retroviral DNA is integrated into the host genome they evolve into endogenous retroviruses that influence eukaryotic genomes So many endogenous retroviruses have inserted themselves into eukaryotic genomes that they allow insight into biology between viral host interactions and the role of retrotransposons in evolution and disease Many retrotransposons share features with endogenous retroviruses the property of recognising and fusing with the host genome However there is a key difference between retroviruses and retrotransposons which is indicated by the env gene Although similar to the gene carrying out the same function in retroviruses the env gene is used to determine whether the gene is retroviral or retrotransposon If the gene is retroviral it can evolve from a retrotransposon into a retrovirus They differ by the order of sequences in pol genes Env genes are found in LTR retrotransposon types Ty1 copia Pseudoviridae Ty3 gypsy Metaviridae and BEL Pao 11 10 They encode glycoproteins on the retrovirus envelope needed for entry into the host cell Retroviruses can move between cells whereas LTR retrotransposons can only move themselves into the genome of the same cell 12 Many vertebrate genes were formed from retroviruses and LTR retrotransposons One endogenous retrovirus or LTR retrotransposon has the same function and genomic locations in different species suggesting their role in evolution 13 Non LTR retrotransposons EditLike LTR retrotransposons non LTR retrotransposons contain genes for reverse transcriptase RNA binding protein nuclease and sometimes ribonuclease H domain 14 but they lack the long terminal repeats RNA binding proteins bind the RNA transposition intermediate and nucleases are enzymes that break phosphodiester bonds between nucleotides in nucleic acids Instead of LTRs non LTR retrotransposons have short repeats that can have an inverted order of bases next to each other aside from direct repeats found in LTR retrotransposons that is just one sequence of bases repeating itself Although they are retrotransposons they cannot carry out reverse transcription using an RNA transposition intermediate in the same way as LTR retrotransposons Those two key components of the retrotransposon are still necessary but the way they are incorporated into the chemical reactions is different This is because unlike LTR retrotransposons non LTR retrotransposons do not contain sequences that bind tRNA They mostly fall into two types LINEs and SINEs SVA elements are the exception between the two as they share similarities with both LINEs and SINEs containing Alu elements and different numbers of the same repeat SVAs are shorter than LINEs but longer than SINEs While historically viewed as junk DNA research suggests in some cases both LINEs and SINEs were incorporated into novel genes to form new functions 15 LINEs Edit Main article Long interspersed nuclear element When a LINE is transcribed the transcript contains an RNA polymerase II promoter that ensures LINEs can be copied into whichever location it inserts itself into RNA polymerase II is the enzyme that transcribes genes into mRNA transcripts The ends of LINE transcripts are rich in multiple adenines 16 the bases that are added at the end of transcription so that LINE transcripts would not be degraded This transcript is the RNA transposition intermediate The RNA transposition intermediate moves from the nucleus into the cytoplasm for translation This gives the two coding regions of a LINE that in turn binds back to the RNA it is transcribed from The LINE RNA then moves back into the nucleus to insert into the eukaryotic genome LINEs insert themselves into regions of the eukaryotic genome that are rich in bases AT At AT regions LINE uses its nuclease to cut one strand of the eukaryotic double stranded DNA The adenine rich sequence in LINE transcript base pairs with the cut strand to flag where the LINE will be inserted with hydroxyl groups Reverse transcriptase recognises these hydroxyl groups to synthesise LINE retrotransposon where the DNA is cut Like with LTR retrotransposons this new inserted LINE contains eukaryotic genome information so it can be copied and pasted into other genomic regions easily The information sequences are longer and more variable than those in LTR retrotransposons Most LINE copies have variable length at the start because reverse transcription usually stops before DNA synthesis is complete In some cases this causes RNA polymerase II promoter to be lost so LINEs cannot transpose further 17 Genetic structure of murine LINE1 and SINEs Bottom proposed structure of L1 RNA protein RNP complexes ORF1 proteins form trimers exhibiting RNA binding and nucleic acid chaperone activity 18 Human L1 Edit Main article LINE1 LINE 1 L1 retrotransposons make up a significant portion of the human genome with an estimated 500 000 copies per genome Genes encoding for human LINE1 usually have their transcription inhibited by methyl groups binding to its DNA carried out by PIWI proteins and enzymes DNA methyltransferases L1 retrotransposition can disrupt the nature of genes transcribed by pasting themselves inside or near genes which could in turn lead to human disease LINE1s can only retrotranspose in some cases to form different chromosome structures contributing to differences in genetics between individuals 19 There is an estimate of 80 100 active L1s in the reference genome of the Human Genome Project and an even smaller number of L1s within those active L1s retrotranspose often L1 insertions have been associated with tumorigenesis by activating cancer related genes oncogenes and diminishing tumor suppressor genes Each human LINE1 contains two regions from which gene products can be encoded The first coding region contains a leucine zipper protein involved in protein protein interactions and a protein that binds to the terminus of nucleic acids The second coding region has a purine pyrimidine nuclease reverse transcriptase and protein rich in amino acids cysteines and histidines The end of the human LINE1 as with other retrotransposons is adenine rich 20 21 22 SINEs Edit Main article Short interspersed nuclear element SINEs are much shorter 300bp than LINEs 23 They share similarity with genes transcribed by RNA polymerase II the enzyme that transcribes genes into mRNA transcripts and the initiation sequence of RNA polymerase III the enzyme that transcribes genes into ribosomal RNA tRNA and other small RNA molecules 24 SINEs such as mammalian MIR elements have tRNA gene at the start and adenine rich at the end like in LINEs SINEs do not encode a functional reverse transcriptase protein and rely on other mobile transposons especially LINEs 25 SINEs exploit LINE transposition components despite LINE binding proteins prefer binding to LINE RNA SINEs cannot transpose by themselves because they cannot encode SINE transcripts They usually consist of parts derived from tRNA and LINEs The tRNA portion contains an RNA polymerase III promoter which the same kind of enzyme as RNA polymerase II This makes sure the LINE copies would be transcribed into RNA for further transposition The LINE component remains so LINE binding proteins can recognise the LINE part of the SINE Alu elements Edit Main article Alu element Alus are the most common SINE in primates They are approximately 350 base pairs long do not encode proteins and can be recognized by the restriction enzyme AluI hence the name Their distribution may be important in some genetic diseases and cancers Copy and pasting Alu RNA requires the Alu s adenine rich end and the rest of the sequence bound to a signal The signal bound Alu can then associate with ribosomes LINE RNA associates on the same ribosomes as the Alu Binding to the same ribosome allows Alus of SINEs to interact with LINE This simultaneous translation of Alu element and LINE allows SINE copy and pasting SVA elements EditSVA elements are present at lower levels than SINES and LINEs in humans The starts of SVA and Alu elements are similar followed by repeats and an end similar to endogenous retrovirus LINEs bind to sites flanking SVA elements to transpose them SVA are one of the youngest transposons in great apes genome and among the most active and polymorphic in the human population Role in human disease EditRetrotransposons ensure they are not lost by chance by occurring only in cell genetics that can be passed on from one generation to the next from parent gametes However LINEs can transpose into the human embryo cells that eventually develop into the nervous system raising the question whether this LINE retrotransposition affects brain function LINE retrotransposition is also a feature of several cancers but it is unclear whether retrotransposition itself causes cancer instead of just a symptom Uncontrolled retrotransposition is bad for both the host organism and retrotransposons themselves so they have to be regulated Retrotransposons are regulated by RNA interference RNA interference is carried out by a bunch of short non coding RNAs The short non coding RNA interacts with protein Argonaute to degrade retrotransposon transcripts and change their DNA histone structure to reduce their transcription Role in evolution EditLTR retrotransposons came about later than non LTR retrotransposons possibly from an ancestral non LTR retrotransposon acquiring an integrase from a DNA transposon Retroviruses gained additional properties to their virus envelopes by taking the relevant genes from other viruses using the power of LTR retrotransposon Due to their retrotransposition mechanism retrotransposons amplify in number quickly composing 40 of the human genome The insertion rates for LINE1 Alu and SVA elements are 1 200 1 20 1 20 and 1 900 respectively The LINE1 insertion rates have varied a lot over the past 35 million years so they indicate points in genome evolution Notably a large number of 100 kilobases in the maize genome show variety due to the presence or absence of retrotransposons However since maize is unusual genetically as compared to other plants it cannot be used to predict retrotransposition in other plants Mutations caused by retrotransposons include Gene inactivation Changing gene regulation Changing gene products Acting as DNA repair sitesRole in biotechnology EditThis section is empty You can help by adding to it January 2021 See also EditCopy number variation Genomic organization Insertion sequences Interspersed repeat Paleogenetics Paleovirology RetrOryza Retrotransposon markers a powerful method of reconstructing phylogenies Tn3 transposon Transposon RetronReferences Edit Dombroski BA Feng Q Mathias SL Sassaman DM Scott AF Kazazian HH Boeke JD July 1994 An in vivo assay for the reverse transcriptase of human retrotransposon L1 in Saccharomyces cerevisiae Molecular and Cellular Biology 14 7 4485 92 doi 10 1128 mcb 14 7 4485 PMC 358820 PMID 7516468 SanMiguel P Bennetzen JL 1998 Evidence that a recent increase in maize genome size was caused by the massive amplification of intergene retrotranposons Annals of Botany 82 Suppl A 37 44 doi 10 1006 anbo 1998 0746 Lander ES Linton LM Birren B Nusbaum C Zody MC Baldwin J et al February 2001 Initial sequencing and analysis of the human genome Nature 409 6822 860 921 Bibcode 2001Natur 409 860L doi 10 1038 35057062 PMID 11237011 Sanchez DH Gaubert H Drost HG Zabet NR Paszkowski J November 2017 High frequency recombination between members of an LTR retrotransposon family during transposition bursts Nature Communications 8 1 1283 Bibcode 2017NatCo 8 1283S doi 10 1038 s41467 017 01374 x PMC 5668417 PMID 29097664 Drost HG Sanchez DH December 2019 Becoming a Selfish Clan Recombination Associated to Reverse Transcription in LTR Retrotransposons Genome Biology and Evolution 11 12 3382 3392 doi 10 1093 gbe evz255 PMC 6894440 PMID 31755923 a b Monga I Banerjee I November 2019 Computational Identification of piRNAs Using Features Based on RNA Sequence Structure Thermodynamic and Physicochemical Properties Current Genomics 20 7 508 518 doi 10 2174 1389202920666191129112705 PMC 7327968 PMID 32655289 Xiong Y Eickbush TH October 1990 Origin and evolution of retroelements based upon their reverse transcriptase sequences The EMBO Journal 9 10 3353 62 doi 10 1002 j 1460 2075 1990 tb07536 x PMC 552073 PMID 1698615 Munoz Lopez M Garcia Perez JL April 2010 DNA transposons nature and applications in genomics Current Genomics 11 2 115 128 doi 10 2174 138920210790886871 PMC 2874221 PMID 20885819 Finnegan DJ June 2012 Retrotransposons Current Biology 22 11 R432 R437 doi 10 1016 j cub 2012 04 025 PMID 22677280 S2CID 235311959 a b Wicker T Sabot F Hua Van A Bennetzen JL Capy P Chalhoub B Flavell A Leroy P Morgante M Panaud O Paux E SanMiguel P Schulman AH December 2007 A unified classification system for eukaryotic transposable elements Nature Reviews Genetics 8 12 973 82 doi 10 1038 nrg2165 PMID 17984973 S2CID 32132898 Copeland CS Mann VH Morales ME Kalinna BH Brindley PJ February 2005 The Sinbad retrotransposon from the genome of the human blood fluke Schistosoma mansoni and the distribution of related Pao like elements BMC Evolutionary Biology 5 1 20 doi 10 1186 1471 2148 5 20 PMC 554778 PMID 15725362 Havecker ER Gao X Voytas DF 18 May 2004 The diversity of LTR retrotransposons Genome Biology 5 225 225 doi 10 1186 gb 2004 5 6 225 PMC 463057 PMID 15186483 Naville M Warren IA Haftek Terreau Z Chalopin D Brunet F Levin P Galiana D Volff JN 17 February 2016 Not so bad after all retroviruses and long terminal repeat retrotransposons as a source of new genes in vertebrates Clinical Microbiology and Infection 22 4 312 323 doi 10 1016 j cmi 2016 02 001 PMID 26899828 Yadav VP Mandal PK Rao DN Bhattacharya S December 2009 Characterization of the restriction enzyme like endonuclease encoded by the Entamoeba histolytica non long terminal repeat retrotransposon EhLINE1 The FEBS Journal 276 23 7070 82 doi 10 1111 j 1742 4658 2009 07419 x PMID 19878305 S2CID 30791213 Santangelo AM de Souza FS Franchini LF Bumaschny VF Low MJ Rubinstein M October 2007 Ancient exaptation of a CORE SINE retroposon into a highly conserved mammalian neuronal enhancer of the proopiomelanocortin gene PLOS Genetics 3 10 1813 26 doi 10 1371 journal pgen 0030166 PMC 2000970 PMID 17922573 Liang KH Yeh CT May 2013 A gene expression restriction network mediated by sense and antisense Alu sequences located on protein coding messenger RNAs BMC Genomics 14 325 doi 10 1186 1471 2164 14 325 PMC 3655826 PMID 23663499 Singer MF March 1982 SINEs and LINEs highly repeated short and long interspersed sequences in mammalian genomes Cell 28 3 433 4 doi 10 1016 0092 8674 82 90194 5 PMID 6280868 S2CID 22129236 Walter M 2015 Transposon regulation upon dynamic loss of DNA methylation PDF Download Available ResearchGate doi 10 13140 rg 2 2 18747 21286 Chueh AC Northrop EL Brettingham Moore KH Choo KH Wong LH January 2009 Bickmore WA ed LINE retrotransposon RNA is an essential structural and functional epigenetic component of a core neocentromeric chromatin PLOS Genetics 5 1 e1000354 doi 10 1371 journal pgen 1000354 PMC 2625447 PMID 19180186 Doucet AJ Hulme AE Sahinovic E Kulpa DA Moldovan JB Kopera HC Athanikar JN Hasnaoui M Bucheton A Moran JV Gilbert N October 2010 Characterization of LINE 1 ribonucleoprotein particles PLOS Genetics 6 10 e1001150 doi 10 1371 journal pgen 1001150 PMC 2951350 PMID 20949108 Denli AM Narvaiza I Kerman BE Pena M Benner C Marchetto MC Diedrich JK Aslanian A Ma J Moresco JJ Moore L Hunter T Saghatelian A Gage FH October 2015 Primate specific ORF0 contributes to retrotransposon mediated diversity Cell 163 3 583 93 doi 10 1016 j cell 2015 09 025 PMID 26496605 S2CID 10525450 Ohshima K Okada N 2005 SINEs and LINEs symbionts of eukaryotic genomes with a common tail Cytogenetic and Genome Research 110 1 4 475 90 doi 10 1159 000084981 PMID 16093701 S2CID 42841487 Stansfield WD King RC 1997 A dictionary of genetics 5th ed Oxford Oxfordshire Oxford University Press ISBN 978 0 19 509441 1 Kramerov DA Vassetzky NS 2005 Short retroposons in eukaryotic genomes International Review of Cytology 247 165 221 doi 10 1016 s0074 7696 05 47004 7 PMID 16344113 Dewannieux M Esnault C Heidmann T September 2003 LINE mediated retrotransposition of marked Alu sequences Nature Genetics 35 1 41 8 doi 10 1038 ng1223 PMID 12897783 S2CID 32151696 Retrieved from https en wikipedia org w index php title Retrotransposon amp oldid 1133407740, wikipedia, wiki, book, books, library,

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