Warning: Undefined array key "mm" in /www/wwwroot/www.ai-bt.com/si.php on line 10 Deprecated: trim(): Passing null to parameter #1 ($string) of type string is deprecated in /www/wwwroot/www.ai-bt.com/si.php on line 10 Targeted nuclear import of open reading frame 1 protein is required for in vivo retrotransposition of a telomere-specific non-long terminal repeat retrotransposon, SART1.

Literature DB >> 14673147

Targeted nuclear import of open reading frame 1 protein is required for in vivo retrotransposition of a telomere-specific non-long terminal repeat retrotransposon, SART1.

Takumi Matsumoto¹, Hidekazu Takahashi, Haruhiko Fujiwara.

Abstract

Non-long terminal repeat (non-LTR) retrotransposons, most of which carry two open reading frames (ORFs), are abundant mobile elements that are distributed widely among eukaryotes. ORF2 encodes enzymatic domains, such as reverse transcriptase, that are conserved in all retroelements, but the functional roles of ORF1 in vivo are little understood. We show with green fluorescent protein-ORF1 fusion proteins that the ORF1 proteins of SART1, a telomeric repeat-specific non-LTR retrotransposon in Bombyx mori, are transported into the nucleus to produce a dotted localization pattern. Nuclear localization signals N1 (RRKR) and N2 (PSKRGRG) at the N terminus and a highly basic region in the center of SART1 ORF1 are involved in nuclear import and the dotted localization pattern in the nucleus, respectively. An in vivo retrotransposition assay clarified that at least three ORF1 domains, N1/N2, the central basic domain, and CCHC zinc fingers are required for SART1 retrotransposition. The nuclear import activity of SART1 ORF1 makes it clear that the ORF1 proteins of non-LTR retrotransposons work mainly in the nucleus, in contrast to the cytoplasmic action of Gag proteins of LTR elements. The functional domains found here in SART1 ORF1 will be useful for developing a more efficient and target-specific LINE-based gene delivery vector.

Entities: Species

Mesh：

Substances：
Retroelements

Year: 2004 PMID： 14673147 PMCID： PMC303349 DOI： 10.1128/MCB.24.1.105-122.2004

Source DB: PubMed Journal: Mol Cell Biol ISSN： 0270-7306 Impact factor: 4.272

38 in total

1. Initial sequencing and analysis of the human genome.

Authors: E S Lander; L M Linton; B Birren; C Nusbaum; M C Zody; J Baldwin; K Devon; K Dewar; M Doyle; W FitzHugh; R Funke; D Gage; K Harris; A Heaford; J Howland; L Kann; J Lehoczky; R LeVine; P McEwan; K McKernan; J Meldrim; J P Mesirov; C Miranda; W Morris; J Naylor; C Raymond; M Rosetti; R Santos; A Sheridan; C Sougnez; Y Stange-Thomann; N Stojanovic; A Subramanian; D Wyman; J Rogers; J Sulston; R Ainscough; S Beck; D Bentley; J Burton; C Clee; N Carter; A Coulson; R Deadman; P Deloukas; A Dunham; I Dunham; R Durbin; L French; D Grafham; S Gregory; T Hubbard; S Humphray; A Hunt; M Jones; C Lloyd; A McMurray; L Matthews; S Mercer; S Milne; J C Mullikin; A Mungall; R Plumb; M Ross; R Shownkeen; S Sims; R H Waterston; R K Wilson; L W Hillier; J D McPherson; M A Marra; E R Mardis; L A Fulton; A T Chinwalla; K H Pepin; W R Gish; S L Chissoe; M C Wendl; K D Delehaunty; T L Miner; A Delehaunty; J B Kramer; L L Cook; R S Fulton; D L Johnson; P J Minx; S W Clifton; T Hawkins; E Branscomb; P Predki; P Richardson; S Wenning; T Slezak; N Doggett; J F Cheng; A Olsen; S Lucas; C Elkin; E Uberbacher; M Frazier; R A Gibbs; D M Muzny; S E Scherer; J B Bouck; E J Sodergren; K C Worley; C M Rives; J H Gorrell; M L Metzker; S L Naylor; R S Kucherlapati; D L Nelson; G M Weinstock; Y Sakaki; A Fujiyama; M Hattori; T Yada; A Toyoda; T Itoh; C Kawagoe; H Watanabe; Y Totoki; T Taylor; J Weissenbach; R Heilig; W Saurin; F Artiguenave; P Brottier; T Bruls; E Pelletier; C Robert; P Wincker; D R Smith; L Doucette-Stamm; M Rubenfield; K Weinstock; H M Lee; J Dubois; A Rosenthal; M Platzer; G Nyakatura; S Taudien; A Rump; H Yang; J Yu; J Wang; G Huang; J Gu; L Hood; L Rowen; A Madan; S Qin; R W Davis; N A Federspiel; A P Abola; M J Proctor; R M Myers; J Schmutz; M Dickson; J Grimwood; D R Cox; M V Olson; R Kaul; C Raymond; N Shimizu; K Kawasaki; S Minoshima; G A Evans; M Athanasiou; R Schultz; B A Roe; F Chen; H Pan; J Ramser; H Lehrach; R Reinhardt; W R McCombie; M de la Bastide; N Dedhia; H Blöcker; K Hornischer; G Nordsiek; R Agarwala; L Aravind; J A Bailey; A Bateman; S Batzoglou; E Birney; P Bork; D G Brown; C B Burge; L Cerutti; H C Chen; D Church; M Clamp; R R Copley; T Doerks; S R Eddy; E E Eichler; T S Furey; J Galagan; J G Gilbert; C Harmon; Y Hayashizaki; D Haussler; H Hermjakob; K Hokamp; W Jang; L S Johnson; T A Jones; S Kasif; A Kaspryzk; S Kennedy; W J Kent; P Kitts; E V Koonin; I Korf; D Kulp; D Lancet; T M Lowe; A McLysaght; T Mikkelsen; J V Moran; N Mulder; V J Pollara; C P Ponting; G Schuler; J Schultz; G Slater; A F Smit; E Stupka; J Szustakowki; D Thierry-Mieg; J Thierry-Mieg; L Wagner; J Wallis; R Wheeler; A Williams; Y I Wolf; K H Wolfe; S P Yang; R F Yeh; F Collins; M S Guyer; J Peterson; A Felsenfeld; K A Wetterstrand; A Patrinos; M J Morgan; P de Jong; J J Catanese; K Osoegawa; H Shizuya; S Choi; Y J Chen; J Szustakowki
Journal: Nature Date: 2001-02-15 Impact factor: 49.962

Review 2. Journey to the center of the cell.

Authors: B R Cullen
Journal: Cell Date: 2001-06-15 Impact factor: 41.582

3. Transplantation of target site specificity by swapping the endonuclease domains of two LINEs.

Authors: Hidekazu Takahashi; Haruhiko Fujiwara
Journal: EMBO J Date: 2002-02-01 Impact factor: 11.598

4. Element-specific localization of Drosophila retrotransposon Gag proteins occurs in both nucleus and cytoplasm.

Authors: S Rashkova; S E Karam; M-L Pardue
Journal: Proc Natl Acad Sci U S A Date: 2002-03-12 Impact factor: 11.205

Review 5. LINE drive. retrotransposition and genome instability.

Authors: Haig H Kazazian; John L Goodier
Journal: Cell Date: 2002-08-09 Impact factor: 41.582

6. Genomic deletions created upon LINE-1 retrotransposition.

Authors: Nicolas Gilbert; Sheila Lutz-Prigge; John V Moran
Journal: Cell Date: 2002-08-09 Impact factor: 41.582

Review 7. Nucleocytoplasmic transport: signals, mechanisms and regulation.

Authors: E A Nigg
Journal: Nature Date: 1997-04-24 Impact factor: 49.962

8. Human l1 retrotransposition is associated with genetic instability in vivo.

Authors: David E Symer; Carla Connelly; Suzanne T Szak; Emerita M Caputo; Gregory J Cost; Giovanni Parmigiani; Jef D Boeke
Journal: Cell Date: 2002-08-09 Impact factor: 41.582

9. High-affinity, non-sequence-specific RNA binding by the open reading frame 1 (ORF1) protein from long interspersed nuclear element 1 (LINE-1).

Authors: Vladimir O Kolosha; Sandra L Martin
Journal: J Biol Chem Date: 2002-12-27 Impact factor: 5.157

10. Gag proteins of the two Drosophila telomeric retrotransposons are targeted to chromosome ends.

Authors: Svetlana Rashkova; Sarah E Karam; Rebecca Kellum; Mary-Lou Pardue
Journal: J Cell Biol Date: 2002-11-04 Impact factor: 10.539

12 in total

1. Essential motifs in the 3' untranslated region required for retrotransposition and the precise start of reverse transcription in non-long-terminal-repeat retrotransposon SART1.

Authors: Mizuko Osanai; Hidekazu Takahashi; Kenji K Kojima; Mitsuhiro Hamada; Haruhiko Fujiwara
Journal: Mol Cell Biol Date: 2004-09 Impact factor: 4.272

2. Eukaryotic translational coupling in UAAUG stop-start codons for the bicistronic RNA translation of the non-long terminal repeat retrotransposon SART1.

Authors: Kenji K Kojima; Takumi Matsumoto; Haruhiko Fujiwara
Journal: Mol Cell Biol Date: 2005-09 Impact factor: 4.272

3. Essential domains for ribonucleoprotein complex formation required for retrotransposition of telomere-specific non-long terminal repeat retrotransposon SART1.

Authors: Takumi Matsumoto; Mitsuhiro Hamada; Mizuko Osanai; Haruhiko Fujiwara
Journal: Mol Cell Biol Date: 2006-07 Impact factor: 4.272

Review 4. Integration site selection by retroviruses and transposable elements in eukaryotes.

Authors: Tania Sultana; Alessia Zamborlini; Gael Cristofari; Pascale Lesage
Journal: Nat Rev Genet Date: 2017-03-13 Impact factor: 53.242

5. Both the Exact Target Site Sequence and a Long Poly(A) Tail Are Required for Precise Insertion of the 18S Ribosomal DNA-Specific Non-Long Terminal Repeat Retrotransposon R7Ag.

Authors: Narisu Nichuguti; Mayumi Hayase; Haruhiko Fujiwara
Journal: Mol Cell Biol Date: 2016-05-02 Impact factor: 4.272