The Key Features of RNA Silencing

Kuniaki Saito; Keita Miyoshi; Mikiko C. Siomi; Haruhiko Siomi

doi:10.1007/978-3-642-12168-5_1

The Key Features of RNA Silencing

Kuniaki Saito, Keita Miyoshi, Mikiko C. Siomi, Haruhiko Siomi

Department of Molecular Biology

Research output: Chapter in Book/Report/Conference proceeding › Chapter

Abstract

The discovery by Fire and Mello in 1998 of sequence-specific gene silencing as a response to double-stranded RNAs (dsRNAs), termed RNA interference (RNAi), has had an enormous impact on biology. In RNAi and related pathways, small noncoding RNAs of 20–30 nucleotides (nt) guide regulatory complexes to RNA targets via base-pairing and promote the inactivation of homologous sequences by a variety of mechanisms, thereby adding a great level of complexity to the way cells regulate protein levels. These pathways, which are collectively referred to as RNA silencing, mediate biological activities that fall into two broad categories; genomic surveillance and gene regulation. RNA silencing occurs in a variety of organisms and is evolutionarily conserved. Central to these processes is small RNA generation by Dicer and inactivation of cognate RNA targets by small RNA–Argonaute complexes acting in combination with a multitude of interacting and collaborating proteins. In some systems, silencing signals are amplified and small RNAs are produced by a Dicer-independent pathway, which challenges our perception and definition of RNAi. There has been remarkable progress in our understanding of the mechanisms underlying RNAi and related silencing processes, which hails the prospect of fully deciphering the RNAi machinery.

Original language	English
Title of host publication	RNA Technologies
Publisher	Springer Science and Business Media Deutschland GmbH
Pages	1-28
Number of pages	28
DOIs	https://doi.org/10.1007/978-3-642-12168-5_1
Publication status	Published - 2010

Publication series

Name	RNA Technologies
ISSN (Print)	2197-9731
ISSN (Electronic)	2197-9758

Keywords

Argonaute
Dicer
RNA Silencing
RNAi
small RNA

ASJC Scopus subject areas

Biochemistry
Molecular Biology
Genetics
Biochemistry, medical
Cancer Research

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1007/978-3-642-12168-5_1

Cite this

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title = "The Key Features of RNA Silencing",

abstract = "The discovery by Fire and Mello in 1998 of sequence-specific gene silencing as a response to double-stranded RNAs (dsRNAs), termed RNA interference (RNAi), has had an enormous impact on biology. In RNAi and related pathways, small noncoding RNAs of 20–30 nucleotides (nt) guide regulatory complexes to RNA targets via base-pairing and promote the inactivation of homologous sequences by a variety of mechanisms, thereby adding a great level of complexity to the way cells regulate protein levels. These pathways, which are collectively referred to as RNA silencing, mediate biological activities that fall into two broad categories; genomic surveillance and gene regulation. RNA silencing occurs in a variety of organisms and is evolutionarily conserved. Central to these processes is small RNA generation by Dicer and inactivation of cognate RNA targets by small RNA–Argonaute complexes acting in combination with a multitude of interacting and collaborating proteins. In some systems, silencing signals are amplified and small RNAs are produced by a Dicer-independent pathway, which challenges our perception and definition of RNAi. There has been remarkable progress in our understanding of the mechanisms underlying RNAi and related silencing processes, which hails the prospect of fully deciphering the RNAi machinery.",

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author = "Kuniaki Saito and Keita Miyoshi and Siomi, {Mikiko C.} and Haruhiko Siomi",

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AU - Miyoshi, Keita

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AU - Siomi, Haruhiko

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AB - The discovery by Fire and Mello in 1998 of sequence-specific gene silencing as a response to double-stranded RNAs (dsRNAs), termed RNA interference (RNAi), has had an enormous impact on biology. In RNAi and related pathways, small noncoding RNAs of 20–30 nucleotides (nt) guide regulatory complexes to RNA targets via base-pairing and promote the inactivation of homologous sequences by a variety of mechanisms, thereby adding a great level of complexity to the way cells regulate protein levels. These pathways, which are collectively referred to as RNA silencing, mediate biological activities that fall into two broad categories; genomic surveillance and gene regulation. RNA silencing occurs in a variety of organisms and is evolutionarily conserved. Central to these processes is small RNA generation by Dicer and inactivation of cognate RNA targets by small RNA–Argonaute complexes acting in combination with a multitude of interacting and collaborating proteins. In some systems, silencing signals are amplified and small RNAs are produced by a Dicer-independent pathway, which challenges our perception and definition of RNAi. There has been remarkable progress in our understanding of the mechanisms underlying RNAi and related silencing processes, which hails the prospect of fully deciphering the RNAi machinery.

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KW - Dicer

KW - RNA Silencing

KW - RNAi

KW - small RNA

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The Key Features of RNA Silencing

Abstract

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Keywords

ASJC Scopus subject areas

UN SDGs

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