A method for producing transgenic cells using a multi-integrase system on a human artificial chromosome vector.

A method for producing transgenic cells using a multi-integrase system on a human artificial chromosome vector.

The production of cells capable of expressing gene(s) of interest is important for a variety of applications in biomedicine and biotechnology, including gene therapy and animal transgenesis. The ability to insert transgenes at a precise location in the genome, using site-specific recombinases such a...

Full description

Bibliographic Details
Main Authors: Shigeyuki Yamaguchi, Yasuhiro Kazuki, Yuji Nakayama, Eiji Nanba, Mitsuo Oshimura, Tetsuya Ohbayashi
Format: Article
Language:English
Published: Public Library of Science (PLoS) 2011-01-01
Series:PLoS ONE
Online Access:http://europepmc.org/articles/PMC3044732?pdf=render
id doaj-0d66a7631e60492098ad6f419d9d27c6
record_format Article
spelling doaj-0d66a7631e60492098ad6f419d9d27c62020-11-25T01:24:44ZengPublic Library of Science (PLoS)PLoS ONE1932-62032011-01-0162e1726710.1371/journal.pone.0017267A method for producing transgenic cells using a multi-integrase system on a human artificial chromosome vector.Shigeyuki YamaguchiYasuhiro KazukiYuji NakayamaEiji NanbaMitsuo OshimuraTetsuya OhbayashiThe production of cells capable of expressing gene(s) of interest is important for a variety of applications in biomedicine and biotechnology, including gene therapy and animal transgenesis. The ability to insert transgenes at a precise location in the genome, using site-specific recombinases such as Cre, FLP, and ΦC31, has major benefits for the efficiency of transgenesis. Recent work on integrases from ΦC31, R4, TP901-1 and Bxb1 phages demonstrated that these recombinases catalyze site-specific recombination in mammalian cells. In the present study, we examined the activities of integrases on site-specific recombination and gene expression in mammalian cells. We designed a human artificial chromosome (HAC) vector containing five recombination sites (ΦC31 attP, R4 attP, TP901-1 attP, Bxb1 attP and FRT; multi-integrase HAC vector) and de novo mammalian codon-optimized integrases. The multi-integrase HAC vector has several functions, including gene integration in a precise locus and avoiding genomic position effects; therefore, it was used as a platform to investigate integrase activities. Integrases carried out site-specific recombination at frequencies ranging from 39.3-96.8%. Additionally, we observed homogenous gene expression in 77.3-87.5% of colonies obtained using the multi-integrase HAC vector. This vector is also transferable to another cell line, and is capable of accepting genes of interest in this environment. These data suggest that integrases have high DNA recombination efficiencies in mammalian cells. The multi-integrase HAC vector enables us to produce transgene-expressing cells efficiently and create platform cell lines for gene expression.http://europepmc.org/articles/PMC3044732?pdf=render
collection DOAJ
language English
format Article
sources DOAJ
author Shigeyuki Yamaguchi
Yasuhiro Kazuki
Yuji Nakayama
Eiji Nanba
Mitsuo Oshimura
Tetsuya Ohbayashi
spellingShingle Shigeyuki Yamaguchi
Yasuhiro Kazuki
Yuji Nakayama
Eiji Nanba
Mitsuo Oshimura
Tetsuya Ohbayashi
A method for producing transgenic cells using a multi-integrase system on a human artificial chromosome vector.
PLoS ONE
author_facet Shigeyuki Yamaguchi
Yasuhiro Kazuki
Yuji Nakayama
Eiji Nanba
Mitsuo Oshimura
Tetsuya Ohbayashi
author_sort Shigeyuki Yamaguchi
title A method for producing transgenic cells using a multi-integrase system on a human artificial chromosome vector.
title_short A method for producing transgenic cells using a multi-integrase system on a human artificial chromosome vector.
title_full A method for producing transgenic cells using a multi-integrase system on a human artificial chromosome vector.
title_fullStr A method for producing transgenic cells using a multi-integrase system on a human artificial chromosome vector.
title_full_unstemmed A method for producing transgenic cells using a multi-integrase system on a human artificial chromosome vector.
title_sort method for producing transgenic cells using a multi-integrase system on a human artificial chromosome vector.
publisher Public Library of Science (PLoS)
series PLoS ONE
issn 1932-6203
publishDate 2011-01-01
description The production of cells capable of expressing gene(s) of interest is important for a variety of applications in biomedicine and biotechnology, including gene therapy and animal transgenesis. The ability to insert transgenes at a precise location in the genome, using site-specific recombinases such as Cre, FLP, and ΦC31, has major benefits for the efficiency of transgenesis. Recent work on integrases from ΦC31, R4, TP901-1 and Bxb1 phages demonstrated that these recombinases catalyze site-specific recombination in mammalian cells. In the present study, we examined the activities of integrases on site-specific recombination and gene expression in mammalian cells. We designed a human artificial chromosome (HAC) vector containing five recombination sites (ΦC31 attP, R4 attP, TP901-1 attP, Bxb1 attP and FRT; multi-integrase HAC vector) and de novo mammalian codon-optimized integrases. The multi-integrase HAC vector has several functions, including gene integration in a precise locus and avoiding genomic position effects; therefore, it was used as a platform to investigate integrase activities. Integrases carried out site-specific recombination at frequencies ranging from 39.3-96.8%. Additionally, we observed homogenous gene expression in 77.3-87.5% of colonies obtained using the multi-integrase HAC vector. This vector is also transferable to another cell line, and is capable of accepting genes of interest in this environment. These data suggest that integrases have high DNA recombination efficiencies in mammalian cells. The multi-integrase HAC vector enables us to produce transgene-expressing cells efficiently and create platform cell lines for gene expression.
url http://europepmc.org/articles/PMC3044732?pdf=render
work_keys_str_mv AT shigeyukiyamaguchi amethodforproducingtransgeniccellsusingamultiintegrasesystemonahumanartificialchromosomevector
AT yasuhirokazuki amethodforproducingtransgeniccellsusingamultiintegrasesystemonahumanartificialchromosomevector
AT yujinakayama amethodforproducingtransgeniccellsusingamultiintegrasesystemonahumanartificialchromosomevector
AT eijinanba amethodforproducingtransgeniccellsusingamultiintegrasesystemonahumanartificialchromosomevector
AT mitsuooshimura amethodforproducingtransgeniccellsusingamultiintegrasesystemonahumanartificialchromosomevector
AT tetsuyaohbayashi amethodforproducingtransgeniccellsusingamultiintegrasesystemonahumanartificialchromosomevector
AT shigeyukiyamaguchi methodforproducingtransgeniccellsusingamultiintegrasesystemonahumanartificialchromosomevector
AT yasuhirokazuki methodforproducingtransgeniccellsusingamultiintegrasesystemonahumanartificialchromosomevector
AT yujinakayama methodforproducingtransgeniccellsusingamultiintegrasesystemonahumanartificialchromosomevector
AT eijinanba methodforproducingtransgeniccellsusingamultiintegrasesystemonahumanartificialchromosomevector
AT mitsuooshimura methodforproducingtransgeniccellsusingamultiintegrasesystemonahumanartificialchromosomevector
AT tetsuyaohbayashi methodforproducingtransgeniccellsusingamultiintegrasesystemonahumanartificialchromosomevector
_version_ 1725117443864526848

Similar Items