Whole genome computational comparative genomics: A fruitful approach for ascertaining Alu insertion polymorphisms

Wang, Jianxin; Song, Lei; Gonder, Mary Katherine; Azrak, Sami; Ray, David A.; Batzer, Mark A.; Tishkoff, Sarah A.; Liang, Ping

doi:10.1016/j.gene.2005.09.031

Cited by 57 publications

(76 citation statements)

References 51 publications

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“…The first of such active groups are L1 elements, the only active autonomous retrotransposons in the human genome, which are also responsible for the mobilization of nonautonomous retrotransposons [Boissinot et al, 2000[Boissinot et al, , 2004Brouha et al, 2003;Dewannieux et al, 2003]. Among the active nonautonomous groups are Alu elements and SVA elements, a composite type of retrotransposon formed of SINE-R, VNTR, and Alu [Boeke, 1997;Boeke and Chapman, 1991;Deininger and Batzer, 2002;Dewannieux et al, 2003;Ostertag et al, 2000Ostertag et al, , 2002Ostertag et al, , 2003Sassaman et al, 1997;Shen et al, 1994;Wang et al, 2005;Wang et al, 2006]. Many of the insertions derived from these active retrotransposons occurred so recently that they are polymorphic with respect to the presence or absence of the insertion in different human populations, families, or even individuals [Batzer et al, 1994;Deininger, 1991, 2002;Boissinot et al, 2000Boissinot et al, , 2004Badge et al, 2003;Bamshad et al, 2003;Myers et al, 2002;Perna et al, 1992;Sheen et al, 2000;Watkins et al, 2001Watkins et al, , 2003.…”

Section: Introductionmentioning

confidence: 99%

“…A total of 505 polymorphic Alu, 65 L1, and 39 SVA elements were recovered by comparing the trace sequences derived from different library sources [Bennett et al, 2004]. By comparing the two versions of the human genome sequences (public vs. Celera www.celera.com), we have recently identified over 800 polymorphic Alu elements and 150 L1 elements [Wang et al, 2006;authors' unpublished data].…”

Section: Introductionmentioning

confidence: 99%

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dbRIP: A highly integrated database of retrotransposon insertion polymorphisms in humans

et al. 2006

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Communicated by Alastair BrownRetrotransposons constitute over 40% of the human genome and play important roles in the evolution of the genome. Since certain types of retrotransposons, particularly members of the Alu, L1, and SVA families, are still active, their recent and ongoing propagation generates a unique and important class of human genomic diversity/polymorphism (for the presence and absence of an insertion) with some elements known to cause genetic diseases. So far, over 2,300, 500, and 80 Alu, L1, and SVA insertions, respectively, have been reported to be polymorphic and many more are yet to be discovered. We present here the Database of Retrotransposon Insertion Polymorphisms (dbRIP; http://falcon.roswellpark.org:9090), a highly integrated and interactive database of human retrotransposon insertion polymorphisms (RIPs). dbRIP currently contains a nonredundant list of 1,625, 407, and 63 polymorphic Alu, L1, and SVA elements, respectively, or a total of 2,095 RIPs. In dbRIP, we deploy the utilities and annotated data of the genome browser developed at the University of California at Santa Cruz (UCSC) for user-friendly queries and integrative browsing of RIPs along with all other genome annotation information. Users can query the database by a variety of means and have access to the detailed information related to a RIP, including detailed insertion sequences and genotype data. dbRIP represents the first database providing comprehensive, integrative, and interactive compilation of RIP data, and it will be a useful resource for researchers working in the area of human genetics.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

dbRIP: A highly integrated database of retrotransposon insertion polymorphisms in humans

et al. 2006

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“…Subsets of the Y subfamilies are the only known Alu elements currently active in the human genome, with variants of the Y, Ya, and Yb lineages currently dominating activity (Deininger and Batzer 1999;Hedges et al 2004;Mills et al 2007;Belancio et al 2008). There are ;900,000 older subfamily elements in the genome, predominately variants of the Alu S and J (Wang et al 2006), and yet no de novo disease-associated insertions of these older elements have been found (Belancio et al 2008).…”

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confidence: 99%

“…There are at least 15 examples of Ya5 elements that have recently inserted causing disease (Belancio et al 2008), despite there being only 3000 copies in the genome (Wang et al 2006). In contrast, the older subfamilies have a 300-fold greater copy number than Ya5 while having no detectable amplification rate, suggesting that there must be at least a 4500-fold enrichment in activity per Ya5 copy relative to the old Alu subfamily members.…”

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confidence: 99%

Diverse cis factors controlling Alu retrotransposition: What causes Alu elements to die?

Comeaux¹,

Roy-Engel²,

Hedges³

et al. 2009

Genome Res.

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The human genome contains nearly 1.1 million Alu elements comprising roughly 11% of its total DNA content. Alu elements use a copy and paste retrotransposition mechanism that can result in de novo disease insertion alleles. There are nearly 900,000 old Alu elements from subfamilies S and J that appear to be almost completely inactive, and about 200,000 from subfamily Y or younger, which include a few thousand copies of the Ya5 subfamily which makes up the majority of current activity. Given the much higher copy number of the older Alu subfamilies, it is not known why all of the active Alu elements belong to the younger subfamilies. We present a systematic analysis evaluating the observed sequence variation in the different sections of an Alu element on retrotransposition. The length of the longest number of uninterrupted adenines in the A-tail, the degree of A-tail heterogeneity, the length of the 3′ unique end after the A-tail and before the RNA polymerase III terminator, and random mutations found in the right monomer all modulate the retrotransposition efficiency. These changes occur over different evolutionary time frames. The combined impact of sequence changes in all of these regions explains why young Alus are currently causing disease through retrotransposition, and the old Alus have lost their ability to retrotranspose. We present a predictive model to evaluate the retrotransposition capability of individual Alu elements and successfully applied it to identify the first putative source element for a disease-causing Alu insertion in a patient with cystic fibrosis.

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“…Second, many RE insertions were predicted by computational screening, and their polymorphism was not confirmed by subsequent experimental studies. 11,24 Consequently, the selection of Alu insertions required some additional studies to meet the criteria indicated in 'Materials and methods.' At the first computational stage we selected 31 autosomal loci: 18 on chromosomes from 1 to 9 (2 per chromosome) and 13 each on 1 of the remaining human chromosomes (from 10 to 22).…”

Section: Resultsmentioning

confidence: 99%

A new set of markers for human identification based on 32 polymorphic Alu insertions

Mamedov

Shagina²,

Kurnikova³

et al. 2010

Eur J Hum Genet

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A number of genetic systems for human genetic identification based on short tandem repeats or single nucleotide polymorphisms are widely used for crime detection, kinship studies and in analysis of victims of mass disasters. Here, we have developed a new set of 32 molecular genetic markers for human genetic identification based on polymorphic retroelement insertions. Allele frequencies were determined in a group of 90 unrelated individuals from four genetically distant populations of the Russian Federation. The mean match probability and probability of paternal exclusion, calculated based on population data, were 5.53Â10 À14 and 99.784%, respectively. The developed system is cheap and easy to use as compared to all previously published methods. The application of fluorescence-based methods for allele discrimination allows to use the human genetic identification set in automatic and high-throughput formats.

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Whole genome computational comparative genomics: A fruitful approach for ascertaining Alu insertion polymorphisms

Cited by 57 publications

References 51 publications

dbRIP: A highly integrated database of retrotransposon insertion polymorphisms in humans

dbRIP: A highly integrated database of retrotransposon insertion polymorphisms in humans

Diverse cis factors controlling Alu retrotransposition: What causes Alu elements to die?

A new set of markers for human identification based on 32 polymorphic Alu insertions

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