Literature DB >> 8114108

Phylogenetic isolation of a human Alu founder gene: drift to new subfamily identity [corrected].

E P Leeflang1, W M Liu, I N Chesnokov, C W Schmid.   

Abstract

A severe bottleneck in the size of the PV Alu subfamily in the common ancestor of human and gorilla has been used to isolate an Alu source gene. The human PV Alu subfamily consists of about one thousand members which are absent in gorilla and chimpanzee DNA. Exhaustive library screening shows that there are as few as two PV Alus in the gorilla genome. One is gorilla-specific, i.e., absent in the orthologous loci in both human and chimpanzee, suggesting the independent retrotranspositional activity of the PV subfamily in the gorilla lineage. The second of these two gorilla PV Alus is present in both human and chimpanzee DNAs and is the single PV Alu known to precede the radiation of these three species. The orthologous Alu in gibbon DNA resembles the next older Alu subfamily. Thus, this Alu locus is originally templated by a non-PV source gene and acquired characteristic PV sequence variants by mutational drift in situ, consequently becoming the first member and presumptive founder of this PV subfamily.

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Year:  1993        PMID: 8114108     DOI: 10.1007/bf00182741

Source DB:  PubMed          Journal:  J Mol Evol        ISSN: 0022-2844            Impact factor:   2.395


  25 in total

1.  A human-specific subfamily of Alu sequences.

Authors:  M A Batzer; P L Deininger
Journal:  Genomics       Date:  1991-03       Impact factor: 5.736

2.  Structure and variability of recently inserted Alu family members.

Authors:  M A Batzer; G E Kilroy; P E Richard; T H Shaikh; T D Desselle; C L Hoppens; P L Deininger
Journal:  Nucleic Acids Res       Date:  1990-12-11       Impact factor: 16.971

3.  Repeated sequences in DNA. Hundreds of thousands of copies of DNA sequences have been incorporated into the genomes of higher organisms.

Authors:  R J Britten; D E Kohne
Journal:  Science       Date:  1968-08-09       Impact factor: 47.728

4.  Existence of at least three distinct Alu subfamilies.

Authors:  C Willard; H T Nguyen; C W Schmid
Journal:  J Mol Evol       Date:  1987       Impact factor: 2.395

5.  Clustering and subfamily relationships of the Alu family in the human genome.

Authors:  V Slagel; E Flemington; V Traina-Dorge; H Bradshaw; P Deininger
Journal:  Mol Biol Evol       Date:  1987-01       Impact factor: 16.240

Review 6.  The Alu family of dispersed repetitive sequences.

Authors:  C W Schmid; W R Jelinek
Journal:  Science       Date:  1982-06-04       Impact factor: 47.728

7.  A transpositionally and transcriptionally competent Alu subfamily.

Authors:  A G Matera; U Hellmann; C W Schmid
Journal:  Mol Cell Biol       Date:  1990-10       Impact factor: 4.272

8.  Tandemly duplicated alpha globin genes of gibbon.

Authors:  A D Bailey; M Stanhope; J L Slightom; M Goodman; C C Shen; C K Shen
Journal:  J Biol Chem       Date:  1992-09-15       Impact factor: 5.157

Review 9.  Transcriptional regulation and transpositional selection of active SINE sequences.

Authors:  C Schmid; R Maraia
Journal:  Curr Opin Genet Dev       Date:  1992-12       Impact factor: 5.578

10.  Mobility of short interspersed repeats within the chimpanzee lineage.

Authors:  E P Leeflang; I N Chesnokov; C W Schmid
Journal:  J Mol Evol       Date:  1993-12       Impact factor: 2.395
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  19 in total

1.  Whole-genome analysis of Alu repeat elements reveals complex evolutionary history.

Authors:  Alkes L Price; Eleazar Eskin; Pavel A Pevzner
Journal:  Genome Res       Date:  2004-11       Impact factor: 9.043

2.  Alu transcripts: cytoplasmic localisation and regulation by DNA methylation.

Authors:  W M Liu; R J Maraia; C M Rubin; C W Schmid
Journal:  Nucleic Acids Res       Date:  1994-03-25       Impact factor: 16.971

3.  RNA polymerase III promoter and terminator elements affect Alu RNA expression.

Authors:  W M Chu; W M Liu; C W Schmid
Journal:  Nucleic Acids Res       Date:  1995-05-25       Impact factor: 16.971

4.  The decline in human Alu retroposition was accompanied by an asymmetric decrease in SRP9/14 binding to dimeric Alu RNA and increased expression of small cytoplasmic Alu RNA.

Authors:  J Sarrowa; D Y Chang; R J Maraia
Journal:  Mol Cell Biol       Date:  1997-03       Impact factor: 4.272

5.  Characterization of species-specifically amplified SINEs in three salmonid species--chum salmon, pink salmon, and kokanee: the local environment of the genome may be important for the generation of a dominant source gene at a newly retroposed locus.

Authors:  N Takasaki; L Park; M Kaeriyama; A J Gharrett; N Okada
Journal:  J Mol Evol       Date:  1996-02       Impact factor: 2.395

6.  LINEs and SINEs of primate evolution.

Authors:  Miriam K Konkel; Jerilyn A Walker; Mark A Batzer
Journal:  Evol Anthropol       Date:  2010-11-01

7.  Gene conversion as a secondary mechanism of short interspersed element (SINE) evolution.

Authors:  D H Kass; M A Batzer; P L Deininger
Journal:  Mol Cell Biol       Date:  1995-01       Impact factor: 4.272

8.  Sporadic amplification of ID elements in rodents.

Authors:  D H Kass; J Kim; P L Deininger
Journal:  J Mol Evol       Date:  1996-01       Impact factor: 2.395

9.  The role and amplification of the HS Alu subfamily founder gene.

Authors:  T H Shaikh; P L Deininger
Journal:  J Mol Evol       Date:  1996-01       Impact factor: 2.395

10.  Genetic variation of recent Alu insertions in human populations.

Authors:  M A Batzer; S S Arcot; J W Phinney; M Alegria-Hartman; D H Kass; S M Milligan; C Kimpton; P Gill; M Hochmeister; P A Ioannou; R J Herrera; D A Boudreau; W D Scheer; B J Keats; P L Deininger; M Stoneking
Journal:  J Mol Evol       Date:  1996-01       Impact factor: 2.395
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