RNA-induced silencing complex

The RNA-induced silencing complex, or RISC, is a multiprotein complex, specifically a ribonucleoprotein, which incorporates one strand of a single-stranded RNA (ssRNA) fragment, such as microRNA (miRNA), or double stranded small interfering RNA (siRNA).[1] The single strand acts as a template for RISC to recognize complementary messenger RNA (mRNA) transcript. Once found, one of the proteins in RISC, called Argonaute, activates and cleaves the mRNA. This process is called RNA interference (RNAi) and it is found in many eukaryotes; it is a key process in gene silencing and defense against viral infections.[2][3]

Discovery

The biochemical identification of RISC was conducted by Gregory Hannon and his colleagues at the Cold Spring Harbor Laboratory.[4] This was only a couple of years after the discovery of RNA interference in 1998 by Andrew Fire and Craig Mello, who shared the 2006 Nobel Prize in Physiology or Medicine.[2]

Drosophila melanogaster

Hannon and his colleagues attempted to identify the RNAi mechanisms involved in gene silencing, by dsRNAs, in Drosophila cells. Drosophila S2 cells were transfected with a lacZ expression vector to quantify gene expression with β-galactosidase activity. Their results showed co-transfection with lacZ dsRNA significantly reduced β-galactosidase activity compared to control dsRNA. Therefore, dsRNAs control gene expression via sequence complementarity.

S2 cells were then transfected with Drosophila cyclin E dsRNA. Cycline E is an essential gene for cell cycle progression into the S phase. Cyclin E dsRNA arrested the cell cycle at the G1 phase (before the S phase). Therefore, RNAi can target endogenous genes.

In addition, cyclin E dsRNA only diminished cyclin E RNA — a similar result was also shown using dsRNA corresponding to cyclin A which acts in S, G2 and M phases of the cell cycle. This shows the characteristic hallmark of RNAi: the reduced levels of mRNAs correspond to the levels of dsRNA added.

To test whether their observation of decreased mRNA levels was a result of mRNA being targeted directly (as suggested by data from other systems), Drosophila S2 cells were transfected with either Drosophila cyclin E dsRNAs or lacZ dsRNAs and then incubated with synthetic mRNAs for cyclin E or lacZ.

Cells transfected with cyclin E dsRNAs only showed degradation in cyclin E transcripts — the lacZ transcripts were stable. Conversely, cells transfected with lacZ dsRNAs only showed degradation in lacZ transcripts and not cyclin E transcripts. Their results led Hannon and his colleagues to suggest RNAi degrades target mRNA through a 'sequence-specific nuclease activity'. They termed the nuclease enzyme RISC.[4]

Function in RNA interference

The PIWI domain of an Argonaute protein in complex with double-stranded RNA.

Loading of dsRNA

The RNase III Dicer aids RISC in RNA interference by cleaving dsRNA into 21-23 nucleotide long fragments with a two-nucleotide 3' overhang.[5][6] These dsRNA fragments are loaded into RISC and each strand has a different fate based on the asymmetry rule phenomenon.[7][8][9]

Part of the RNA interference pathway with the different ways RISC can silence genes via their messenger RNA.

Gene regulation

RISC uses the bound guide strand to target complementary 3'-untranslated regions (3'UTR) of mRNA transcripts via Watson-Crick base pairing.[12][13] RISC can now regulate gene expression of the mRNA transcript in a number of ways.

mRNA degradation

The most understood function of RISC is degrading target mRNA which reduces the levels of transcript available to be translated by ribosomes. There are two main requirements for mRNA degradation to take place:

mRNA degradation is localised in cytoplasmic bodies called P-bodies.[14]

Translational repression

RISC can modulate the loading of ribosome and accessory factors in translation to repress expression of the bound mRNA transcript. Translational repression only requires a partial sequence match between the guide strand and target mRNA.[13]

Translation can be regulated at the initiation step by:

Translation can be regulated at post-initiation steps by:

There is still speculation on whether translational repression via initiation and post-initiation is mutually exclusive.

Heterochromatin formation

Some RISCs are able to directly target the genome by recruiting histone methyltransferases to form heterochromatin at the gene locus and thereby, silencing the gene. These RISCs take the form of a RNA-induced transcriptional silencing complex (RITS). The best studied example is with the yeast RITS.[13][18][19]

The mechanism is not well understood but RITS degrade nascent mRNA transcripts. It has been suggested this mechanism acts as a 'self-reinforcing feedback loop' as the degraded nascent transcripts are used by RNA-dependent RNA polymerase (RdRp) to generate more siRNAs.[20]

DNA elimination

RISCs seem to have a role in degrading DNA during somatic macronucleus development in protozoa Tetrahymena. It is similar to heterochromatin formation and is implied as a defence against invading genetic elements.[21]

RISC-associated proteins

The complete structure of RISC is still unsolved. Many studies have reported a range of sizes and components for RISC but it is not entirely sure whether this is due to there being a number of RISC complexes or due to the different sources that different studies use.[22]

Table 1: Complexes implicated in RISC assembly and function Based on table by Sontheimer (2005) [22]
Complex Source Known/apparent components Estimated size Apparent function in RNAi pathway
Dcr2-R2D2[23] D. melanogaster S2 cells Dcr2, R2D2 ~250 kDa dsRNA processing, siRNA binding
RLC (A)[24][25] D. melanogaster embryos Dcr2, R2D2 NR dsRNA processing, siRNA binding, precursor to RISC
Holo-RISC[24][25] D. melanogaster embryos Ago 2, Dcr1, Dcr2, Fmr1/Fxr, R2D2, Tsn, Vig ~80S Target-RNA binding and cleavage
RISC[4][26][27][28] D. melanogaster S2 cells Ago2, Fmr1/Fxr, Tsn, Vig ~500 kDa Target-RNA binding and cleavage
RISC[29] D. melanogaster S2 cells Ago2 ~140 kDa Target-RNA binding and cleavage
Fmr1-associated complex[30] D. melanogaster S2 cells L5, L11, 5S rRNA, Fmr1/Fxr, Ago2, Dmp68 NR Possible target-RNA binding and cleavage
Minimal RISC[31][32][33][34] HeLa cells eIF2C1 (Ago1) or eIF2C2 (Ago2) ~160 kDa Target-RNA binding and cleavage
miRNP[35][36] HeLa cells eIF2C2 (ago2), Gemin3, Gemin4 ~550 kDa miRNA association, target-RNA binding and cleavage

Ago, Argonaute; Dcr, Dicer; Dmp68, D. melanogaster orthologue of mammalian p68 RNA unwindase; eIF2C1, eukaryotic translation initiation factor 2C1; eIF2C2, eukaryotic translation initiation factor 2C2; Fmr1/Fxr, D. melanogaster orthologue of the fragile-X mental retardation protein; miRNP, miRNA-protein complex; NR, not reported; Tsn, tudor-staphylococcal nuclease; Vig, vasa intronic gene.

A full-length argonaute protein from the archaea species Pyrococcus furiosus.

Regardless, it is apparent that Argonaute proteins are present and are essential for function. Furthermore, there are insights into some of the key proteins (in addition to Argonaute) within the complex, which allow RISC to carry out its function.

Argonaute proteins

Main article: Argonaute

Argonaute proteins are a family of proteins found in prokaryotes and eukaryotes. Their function in prokaryotes is unknown but in eukaryotes they are responsible for RNAi.[37] There are eight family members in human Argonautes of which only Argonaute 2 is exclusively involved in targeted RNA cleavage in RISC.[34]

The RISC-loading complex allows the loading of dsRNA fragments (generated by Dicer) to be loaded on to Argonaute 2 (with the help of TRBP) as part of the RNA interference pathway.

RISC-loading complex

The RISC-loading complex (RLC) is the essential structure required to load dsRNA fragments into RISC in order to target mRNA. The RLC consists of dicer, the human immunodeficiency virus transactivating response RNA-binding protein (TRBP) and Argonaute 2.

Dicer associates with TRBP and Argonaute 2 to facilitate the transfer of the dsRNA fragments generated by Dicer to Argonaute 2.[38][39]

More recent research has shown the human RNA helicase A could help facilitate the RLC.[40]

Other proteins

Recently identified members of RISC are SND1 and MTDH.[41] SND1 and MTDH are oncogenes and regulate various gene expression.[42]

Table 2: Biochemically documented proteins associated with RISC Based on the table by Sontheimer (2005) [22]
Protein Species the protein is found
Dcr1[24] D. melanogaster
Dcr2[23][24][25] D. melanogaster
R2D2[24][25] D. melanogaster
Ago2[24][26][29][30] D. melanogaster
Dmp68[30] D. melanogaster
Fmr1/Fxr[24][27][30] D. melanogaster
Tsn[24][28] D. melanogaster
Vig[24][27] D. melanogaster
Polyribosomes, ribosome components[4][24][26][30][43] D. melanogaster, T. brucei
eIF2C1 (Ago1)[31] H. sapiens
eIF2C2 (Ago2)[31][32][34][36] H. sapiens
Gemin3[35][36] H. sapiens
Gemin4[35][36] H. sapiens

Ago, Argonaute; Dcr, Dicer; Dmp68, D. melanogaster orthologue of mammalian p68 RNA unwindase; eIF2C1, eukaryotic translation initiation factor 2C1; eIF2C2, eukaryotic translation initiation factor 2C2; Fmr1/Fxr, D. melanogaster orthologue of the fragile-X mental retardation protein; Tsn, tudor-staphylococcal nuclease; Vig, vasa intronic gene.

Binding of mRNA

Diagram of RISC activity with miRNAs

It is as yet unclear how the activated RISC complex locates the mRNA targets in the cell, though it has been shown that the process can occur in situations outside of ongoing protein translation from mRNA.[44]

Endogenously expressed miRNA in metazoans is usually not perfectly complementary to a large number of genes and thus, they modulate expression via translational repression.[45][46] However, in plants, the process has a much greater specificity to target mRNA and usually each miRNA only binds to one mRNA. A greater specificity means mRNA degradation is more likely to occur.[47]

See also

Further reading

External links

References

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