Alu expression in human cell lines and their retrotranspositional potential.

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serval:BIB_6EB3C4A856F3
Type
Article: article from journal or magazin.
Collection
Publications
Institution
Title
Alu expression in human cell lines and their retrotranspositional potential.
Journal
Mobile DNA
Author(s)
Oler A.J., Traina-Dorge S., Derbes R.S., Canella D., Cairns B.R., Roy-Engel A.M.
ISSN
1759-8753 (Electronic)
Publication state
Published
Issued date
2012
Volume
3
Number
1
Pages
11
Language
english
Abstract
BACKGROUND: The vast majority of the 1.1 million Alu elements are retrotranspositionally inactive, where only a few loci referred to as 'source elements' can generate new Alu insertions. The first step in identifying the active Alu sources is to determine the loci transcribed by RNA polymerase III (pol III). Previous genome-wide analyses from normal and transformed cell lines identified multiple Alu loci occupied by pol III factors, making them candidate source elements.
FINDINGS: Analysis of the data from these genome-wide studies determined that the majority of pol III-bound Alus belonged to the older subfamilies Alu S and Alu J, which varied between cell lines from 62.5% to 98.7% of the identified loci. The pol III-bound Alus were further scored for estimated retrotransposition potential (ERP) based on the absence or presence of selected sequence features associated with Alu retrotransposition capability. Our analyses indicate that most of the pol III-bound Alu loci candidates identified lack the sequence characteristics important for retrotransposition.
CONCLUSIONS: These data suggest that Alu expression likely varies by cell type, growth conditions and transformation state. This variation could extend to where the same cell lines in different laboratories present different Alu expression patterns. The vast majority of Alu loci potentially transcribed by RNA pol III lack important sequence features for retrotransposition and the majority of potentially active Alu loci in the genome (scored high ERP) belong to young Alu subfamilies. Our observations suggest that in an in vivo scenario, the contribution of Alu activity on somatic genetic damage may significantly vary between individuals and tissues.
Pubmed
Web of science
Open Access
Yes
Create date
04/07/2013 9:45
Last modification date
20/08/2019 14:27
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