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11 - Viral delivery of shRNA

Published online by Cambridge University Press:  31 July 2009

By
Ying Mao ,
Chris Mello ,
Laurence Lamarcq ,
Brad Scherer ,
Thomas Quinn ,
Patty Wong  and
Andrew Farmer
Edited by
Krishnarao Appasani
Foreword by
Andrew Fire  and
Marshall Nirenberg
Ying Mao
Affiliation:
BD Biosciences Clontech
Chris Mello
Affiliation:
BD Biosciences Clontech
Laurence Lamarcq
Affiliation:
BD Biosciences Clontech
Brad Scherer
Affiliation:
BD Biosciences Clontech
Thomas Quinn
Affiliation:
BD Biosciences Clontech
Patty Wong
Affiliation:
BD Biosciences Clontech
Andrew Farmer
Affiliation:
BD Biosciences Clontech
Krishnarao Appasani
Affiliation:
GeneExpression Systems, Inc., Massachusetts
Andrew Fire
Affiliation:
Stanford University, California
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Summary

Introduction

The completion of the human genome has made available the sequences of thousands of genes (Baltimore, 2001), allowing researchers to switch focus from identifying genes to understanding their function. In broad terms, gene function studies can be classified into two categories: those where the gene of interest is introduced into a system in which it is not expressed, and those in which the gene is disrupted or removed. While over-expression studies are fairly straightforward, methods for gene inactivation have been hampered in higher eukaryotes by the difficulty in manipulating their genetic material. Thus, although it is possible to generate mice lacking genes of interest by homologous recombination (Capecchi, 1989; van der Weyden et al., 2002), such studies remain technically challenging and expensive. Moreover, in some cases, deletion of a gene may be lethal, preventing its analysis (e.g., Lui et al., 1996). Alternatively, the phenotype produced may differ from that expected in humans (Harlow, 1992; Lee et al., 1992). A simple method for effective genetic inactivation in somatic cells in vitro is greatly needed, but has remained elusive (Sedivy and Dutriaux, 1999). Not surprisingly, recent years have seen considerable interest in a novel method for inactivating gene function in somatic cells that exploits the phenomenon of RNA interference (RNAi), first described by Fire et al. (1998). In their seminal study, they showed that double-stranded (ds)RNA homologous to a gene of interest could inhibit its expression. The dsRNA is digested into 21–23 nucleotide small interfering RNAs (siRNAs).

Type
Chapter
Information
RNA Interference Technology
From Basic Science to Drug Development
 , pp. 161 - 173
Publisher: Cambridge University Press
Print publication year: 2005

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