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Vol. 13, No. 2, pp. 139-141, January 15, 1999
Center for Cancer Research and Department of Biology, Massachusetts Institute of Technology, Cambridge, Massachusetts 02139-4307 USA
Double-strand RNA (dsRNA) is a signal for
gene-specific silencing of expression in a number of organisms. This
phenomenon was demonstrated recently in Caenorhabditis elegans
when dsRNA was injected into the worm and the corresponding gene
products disappeared from both the somatic cells of the organism as
well as in its F1 progeny (Fire et al. 1998 Montgomery et al. (1998) Double-strand RNA primarily suppresses gene expression by a
post-transcriptional mechanism in C. elegans (Montgomery et
al. 1998 dsRNA mediated suppression of specific gene expression has also been
observed in plants. One demonstration of the phenomenon follows
expression in plant cells of a recombinant RNA virus containing exonic
sequences of an endogenous cellular gene. Expression of the cellular
gene is suppressed in these cells when the recombinant viral RNAs are
capable of replicating and not when they are replication incompetent
(Angell and Baulcombe 1997 The purest demonstration that dsRNA mediates gene silencing in plants
is the genetic study of Waterhouse et al. (1998) There are indications in C. elegans and direct evidence in
plants that dsRNA may also act by generating a second mechanism, a
silencing of transcription of a specific gene. In plants, the silenced
gene has been shown to be hypermethylated, perhaps contributing to the
inactive state (Wassenegger et al. 1994 The finding that dsRNA may induce the transcriptional silencing of a
specific gene could be important in several biological phenomena. For
example, recent results suggest that the activity of an antisense
promoter in the first intron of the gene for the mouse receptor for the
insulin-like growth factor type-2 (Igf2r) is important for its
paternal-specific repression (Wutz et al. 1997 The cosuppression phenomenon and particularly its post-transcriptional
gene silencing aspect (PTGS) in plants has been studied for a number of
years. Several startling conclusions from these experiments may have
implications for the RNAi effect in other organisms. First, that the
PTGS effect, whether induced by a DNA segment or by a RNA duplex as
part of the replicative intermediates of a RNA virus, is probably
present in the cytoplasm as it inhibits specific gene expression from
RNA viruses that are not known to enter the nucleus. Second, the
gene-specific agents that stimulate or mediate the cosuppression
effects are amplifiable by normal cells and will spread through plants
by both plasmodesmatal and phloem channels (Vionnet et al. 1998 Evidence for amplification of the gene-specific agent comes from
comparison of the amount of input dsRNA and the number of cells and
number of mRNAs in those cells which are suppressed. For example, plant
tissue with the PTGS state can be grafted onto other normal plants with
a resulting spread of the PTGS state into the tissue of the grafted
host (Vionnet et al. 1998 Restriction of infection by RNA viruses is almost certainly one of the
biological consequences of the PTGS or RNAi state. Not surprisingly,
some plant viruses appear to encode gene products which block the
development of the PTGS state (Kasschau and Carrington 1998 The implications of a dsRNA-induced gene-specific silencing mechanism
that is amplified by normal cells are astounding when considered in
molecular terms. The effects discussed above can be diagrammed as
follows:
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References
). This RNA
interference, RNAi, has been generalized to many genes in C. elegans (Montgomery and Fire 1998; Shi and Mello 1998; Tabara et
al. 1998; Timmons and Fire 1998). ds-RNA can also suppress expression
of specific genes in plants, a component of the phenomenon called
cosuppression (Vionnet et al. 1998; Waterhouse et al. 1998). Two recent
reports document dsRNA-mediated interference with expression of
specific genes in other organisms. Double-strand RNA produced
gene-specific phenotypes in Trypanosoma brucei (Ngo et al.
1998) and, very recently, dsRNA-mediated interference was demonstrated
in Drosophila (Kennerdell and Carthew 1998). Thus, the
RNAi phenomenon is likely to be a general mechanism for gene regulation
and may be critical for many developmental and antiviral processes.
have investigated how RNAi suppresses the
expression of endogenous genes in C. elegans. dsRNA might conceivably direct mutations of the endogenous genes thus inactivating function. However, the fact that the F2 progeny from
RNAi-treated C. elegans generally reverted to normal phenotype
argued against nonreversible gene modification. Further sequencing of
the targeted locus failed to detect nucleotide differences, direct
evidence against a mutational mechanism.
). A post-transcriptional mechanism was foreshadowed by earlier experiments showing that dsRNAs from sequences in the mature RNA, that
is, exons, had RNAi activity, whereas dsRNAs from intron sequences did
not (Fire et al. 1998). The most direct evidence for a
post-transcriptional effect arises from analysis of RNAi effects on a
multiple-gene operon. Such operons are expressed in C. elegans
by transcription of long precursor RNAs that are then processed by
trans-splicing and cleavage to generate specific mRNAs. The
lin-15b and lin-15a genes are part of one operon and both need to be inactivated to generate the multivulva phenotype. Injection of dsRNA from both genes generated the phenotype, whereas injection of dsRNA from either gene alone did not. This strongly indicates that suppression of the upstream gene does not inactivate the
downstream gene and thus that the RNAi effect is post-transcriptional. The post-transcriptional effects of RNAi were directly observed using
in situ hybridization to follow transcripts of genes suppressed by
injection of dsRNA (Montgomery et al. 1998). There was a diminution of
nuclear RNA from the suppressed gene as well as a total absence of the
specific mRNA in the cytoplasm. This suggests that dsRNA establishes an
intracellular state that destroys RNA transcribed and spliced from a
specific gene. Both this study and other results are most easily
explained if the specific RNA degradation occurs in both the nucleus
and the cytoplasm.
). Viral RNA replication involves dsRNA. A
similar phenomenon can be observed when a transgene is introduced into
plant cells. The endogenous gene corresponding to the transgene can
become suppressed (e.g., Vionnet et al. 1998), perhaps due to symmetric
transcription of both strands of the transgene. Such symmetric
transcription could arise by initiation in flanking sequences due to
the presence of fortuitous promoter sites in plasmid DNA. The plant and
nematode effects share the property of spreading. Examples of this are
striking. Worms fed dsRNA exhibit a strong systemic interference
phenotype (Timmons and Fire 1998) and introduction (into plants) of
500-bp fragments of a gene absorbed on the surface of a gold bead
projectile can result in suppression of the gene in cells both
immediately adjacent to the site penetrated by the bead as well as at
very distant sites (Vionnet et al. 1998).
. Transgenic plants
were established which expressed either sense or antisense of a gene of
the potato virus Y (PVY). Both transgenic lines of tobacco were
susceptible to PVY infection. However, crosses of these tobacco lines
that expressed transgenes for both the sense and antisense orientation
and thus could generate dsRNA became resistant to PVY. This suggests
that the two complementary RNAs transcribed from unlinked loci were
able to anneal in the nucleus and induce a gene-specific suppressive state.
). In C. elegans, the
only indication of such a gene-linked suppression is that the RNAi
effect for some genes can be transmitted to the F2 generation (Tabara et al. 1998). Silencing of an endogenous locus by transgenes has also been observed in Drosophila (see, e.g., Pal-Bhadra et al. 1997). In these cases, the copy number of the transgene appears to
be important and there is no direct evidence that the silencing mechanism is mediated by dsRNA. One study strongly suggests that the
mechanism of silencing is transcriptional, with the proteins of the
polycomb complex becoming associated with the silenced endogenous locus
(Pal-Bhadra et al. 1997). Polycomb complexes are known to be important
for the silencing of genes during development. In the study, where
dsRNA has been shown to be a potent and specific inhibitor of gene
activity in Drosophila (Kennerdell and Carthew 1998),
transmission through the germ line was not observed. In this case, the
dsRNA was injected into the syncytial blastoderm embryos and it
generated phenotypes in the L1 larvae but not in the progeny.
). In this case, dsRNA
generated by symmetric transcription from the two opposing promoters
might be a signal for establishing the allele-specific repression.
).
Furthermore, the agent(s) of suppression will pass through cells that
do not contain any endogenous gene affected by the cosuppression
effect. This suggests that the agent, which is likely to be composed of
nucleic acids because of its gene-specific origin and effect, can be
transmitted, and probably amplified, by cells utilizing the genetic
information in the agent alone.
). Similarly, a limited amount of dsRNA will
generate RNAi in both the somatic tissue of the worm and the
F1 progeny (Fire et al. 1998). The only alternative
explanation for the remarkable efficiency of the RNAi other than
amplification would be the establishment of a highly catalytic RNA
degradation process. It is possible, in fact likely, that both an
amplification process as well as a catalytic process are part of the
RNAi phenonemon in some organisms.
). The
mechanism of suppression of the dsRNA induced gene-specific silencing
by the viral protein remains to be investigated.
Speculation about the molecular processes, which underlie RNAi
effects, might begin with a previously described mechanism for covalent
modification of dsRNA (Bass and Weintraub 1988
). Most eukaryotic cells
contain one or more adenosine deaminases which convert many of the A
residues in duplex RNA to inosine (I). The product RNA becomes
sufficiently modified that the two strands of the RNA dissociate. This
I-containing RNA is bound by proteins in extracts, so far not
characterized, that are stable to electrophoresis in native complexes
(Wagner and Nishikura 1988). One can speculate that this modified
single strand RNA with bound proteins could be the agent, which
interacts with nuclear and cytoplasmic RNAs, signaling their
degradation. This agent might also be replicated by cellular
polymerases, perhaps RNA polymerase II, which is thought to replicate
viroid-type RNAs in both plant and vertebrate cells. If replicated by a
base-pairing mechanism, the I residues would be converted to G residues
in the product. This type of conversion has been documented during the
replication of RNA viruses where it is manifested as hypermutation of
the viral genome (Bass 1997). Adenosine deamination of nuclear RNA has
been characterized for sense and antisense RNAs from the early region
of the DNA virus polyoma (Kumar and Carmichael 1997). In early-strand
RNA recovered from late infected cells, approximately half of the
adenosines were modified. Interestingly, this modified RNA was
primarily confined to the nucleus and was apparently relatively stable.
In vertebrate systems, dsRNA was long ago recognized as a potent signaling molecule in the induction of interferons and execution of the antiviral state. Briefly, exposure of cells to dsRNA, such as poly(IC), potently induces the transcription of interferons that induce an antiviral state in cells. The antiviral state is characterized by the synthesis of a number of proteins that recognize dsRNA, a common property of the replication intermediates of RNA viruses. These proteins include a kinase, PKR which is activated by dsRNA, a 2'-5'-oligoadenylated synthetase activated by dsRNA and dsRNA-specific adenosine deaminase activities. The PKR kinase activity suppresses translation by phosphorylation of initiation factors and synthesis of oligo-2'-5' poly activates the endoribonuclease RNase L, which degrades RNA. However, neither this suppression of translation nor degradation of mRNA has been shown to be gene-specific in action. In fact, it remains a mystery how cells treated with interferon specifically suppress the translation of viral mRNAs in their cytoplasm and not cellular mRNAs. Perhaps some aspect of the RNAi effect occurs or can be induced in mammalian cells.
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1 E-MAIL sharppa{at}mit.edu; FAX (617) 253-3867.
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