User:Nickysoso/sandbox

This is the user sandbox of Nickysoso. A user sandbox is a subpage of the user's user page. It serves as a testing spot and page development space for the user and is not an encyclopedia article. Create or edit your own sandbox here. Other sandboxes: Main sandbox | Template sandbox Finished writing a draft article? Are you ready to request review of it by an experienced editor for possible inclusion in Wikipedia? Submit your draft for review!

The RNA-induced silencing complex, or RISC, is a ribonucleoprotein complex involved in the RNA interference pathway. The pathway scans the cell for mRNA that are viral in nature or ones that have been transcribed from viral DNA and/or transposable elements in the genome. In doing so, the pathway interferes with the translation process of these mRNA molecules, thereby stopping the production of viral proteins that could be harmful to the cell. As part of this pathway, RISC processes and incorporates microRNA or small interfering RNA produced from viral DNA and/or transposable elements in the genome.^[1] By using the incorporated microRNA or siRNA as a template, the RISC complex searches the cell for mRNA that are complementary to the template. Based on the degree of complementarity between the mRNA and the template, the RISC interferes with the translation of protein from the mRNA. The end result is gene silencing, which is a defense mechanism against viral infections in many eukaryotes.^[2][3]

Discovery of RISC

 

Drosophila melanogaster

RISC was first discovered in 2000 by Gregory Hannon and his colleagues at the Cold Spring Harbor Laboratory.^[4]

Hannon and his colleagues noted that, by introducing double-stranded RNAs into organisms such as C. elegans and Drosophila, gene expression could be inhibited in a sequence-specific manner via RNA interference. They sought out to determine the underlying mechanism behind RNA interference. By introducing double stranded RNAs, a 'loss-of-function' phenotype could appear in cultured Drosophila cells. This was correlated with a decrease in the levels of mRNA in the cells, implying that the absence of mRNA led to the loss of function. The Drosophila cells also contained nuclease activity that specifically cleaved mRNA transcripts that were homologous to the introduced double-stranded RNA. They found that this particular enzyme contained an essential RNA component. The source of this nuclease activity turned out to be a multiprotein complex, later called RISC.^[4]

Structure of RISC

The structure of RISC varies between different organisms and cell types. However, the three most common components are Argonaute, Dicer and TBPR, with Argonaute being present in most RISC. Together, the three components form the RISC-loading complex.^[5]

RISC-loading complex

 

The RISC-loading complex allows the loading of double stranded RNA fragments (generated by TRBP-modulated Dicer) onto Argonaute 2.

The RISC-loading complex (RLC) is the essential structure required to load double stranded RNA fragments into RISC in order to target mRNA. The double-stranded RNA can either be microRNA or small interfering RNA. The RLC consists of dicer, the 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.^[6][7]

Dicer endonuclease

Main article: Dicer

Dicer is an endonuclease that is encoded by the DICER1 gene in humans. Being part of the RNase III family, Dicer cleaves double-stranded RNA (dsRNA) and pre-microRNA (pre-miRNA) into short double-stranded RNA fragments called small interfering RNA and microRNA, respectively. These fragments are approximately 21 to 23 base pairs in length and are then delivered to Argonaute proteins straight after cleavage.^[8]

Argonaute proteins

Main article: Argonaute

A major component of RISC, Argonaute is a ubiquitous protein found in plants, animals and fungi. It holds the dsRNA template received from Dicer and also provides a region in which the dsRNA can interact with the target mRNA. Argonaute then cleaves the mRNA with its endonuclease activity, preventing translation and silencing the gene.^[9][10]

There are many families of Argonaute proteins. The prokaryotic ones are often functionally redundant and can replace one another. The eukaryotic ones differ by the means with which they bind to dsRNA.^[9] The largest family of eukaryotic Argonaute is known as Ago, with Ago2 being the major component of human RISC.^[10]

However, the structure of eukaryotic Argonaute is as of yet unclear. The structures of prokaryotic Argonaute has been better described. The protein has two lobes, each responsible for binding opposite end of the small interfering RNA. The N-terminal lobe contains a PAZ domain, which binds the 3'-end of the dsRNA. On the other hand, the C-terminal lobe contains the middle domain and the PIWI domain. The middle domain binds to the 5'-phosphate of the dsRNA whilst the PIWI domain acts as a RNAse to cleave the target mRNA in a process called 'slicing'. Furthermore, there is a flexible hinge region between the two lobes which provides structural flexibility. This allows the two lobes to pivot around one another, opening a region for the dsRNA template and mRNA template to bind.^[11]

TRBP

TRBP is a Dicer-binding protein that regulates Dicer activity. It works together with another Dicer-binding protein called PACT to regulate Dicer activity, though both may appear functionally redundant on first inspection. When TRBP binds to Dicer, the endonuclease activity of Dicer is activated and Dicer proceeds to cleave 70-base-pair dsRNA into siRNA or microRNA. On the other hand, when PACT binds to Dicer, the endonuclease activity is inhibited, leading to no yield of siRNA or microRNA.^[12]

Role of RISC in RNA interference

 

Part of the RNA interference pathway focusing on RISC

Loading of template RNA

RISC activity is triggered by the appearance of double stranded RNA in the cytoplasm of a eukaryotic cell. The process starts in the nucleus with a precursor microRNA, which is an RNA transcript that can fold back on itself to form a double stranded RNA. The precursor microRNA is cleaved by the ribonuclease Drosha, trimming down to a double stranded molecule which is around 70 base pairs in length and contains hairpins.^[13][14] This RNA molecule is then exported out of the nucleus and into the cytoplasm, where it becomes substrate for the Dicer-containing pre-RISC complex. The Dicer endonuclease trims the 70-base-pair microRNA down to around 21 to 23 base pairs, which is then incorporated into the pre-RISC complex to form an active mature RISC. While incorporated, the double-stranded RNA splits into two single strands. The single strand with the higher free energy is thermodynamically favorable and therefore kept within RISC. This is known as the guide strand. The strand with lower free energy is known as the passenger strand; it detaches from RISC before being degraded.^[15][16][17]

mRNA binding

By this stage, RISC is a ribonucleotide particle containing a single-stranded RNA, known as the guide strand, which is bound to an Argonaute protein. While bound to Argonaute, the bases 2 to 6 of the guide strand protrude out from the structure to face the cytoplasm. This protruding region is known as the seed region and is the primary site for target recognition.^[18][11] This explains why RISC is so efficient in searching the cytoplasm for free-floating mRNA. Once a target is found, the seed region binds to the complementary region on the target. This binding causes a conformational change in the Argonaute which opens up a binding cleft to accommodate for both the guide strand and mRNA target. The level of complementarity between the guide strand and the mRNA will determine the pathway which RISC will take in order to silence the gene: either mRNA degradation or translational repression.^[11]

mRNA degradation

Also known as splicing, mRNA degradation is the simplest silencing pathway. If there is complete complementarity between the guide strand in the RISC and the mRNA, then the nuclease activity of Argonaute 2 is activated. The PIWI domain of Argonaute 2 catalyses the slicing of the target mRNA. The amino acids of the PIWI domain coordinate catalytic metal ions such that a water molecule can perform nucleophilic attack on the phosphodiester backbone of the target mRNA. After hydrolysis, the fragments of the target can still be translated, but the resulting protein product will contain frameshift and stop codons, rendering them dysfunctional and targeted for degradation.^[11][19]

Translational repression

Translational repression is the most prevalent pathway of gene silencing in mammals. If there is incomplete complementarity between the microRNA and target mRNA, the nuclease activity of Ago2 is not activated. Therefore, mRNA is not cleaved and its 3' end remains bound to RISC. This prevents the 3' end of the mRNA from joining with the 5' end. Without circularisation of the mRNA, the ribosome cannot initiate translation and viral protein is not produced.^[20][21]

However, there are two other mechanisms by which RISC can repress translation. Both are from Drosophila but involve different Argonaute proteins. The first pathway involves Ago2 blocking protein-protein interaction within the translation initiation complex. Without the complex, translation cannot occur. The second path involve Ago1 promoting the deadenylation and degradation of the target mRNA.^[11][22]

It is important to note that translational repression can only take place if the Argonaute-bound guide strand is a microRNA. The process cannot occur if the guide strand is a siRNA. In addition, with regards to incomplete complementarity, the only region on the microRNA that is required to be complementary to the mRNA is bases 2 to 7.^[11]

Heterochromatin formation

Instead of binding to mRNA like in the previous two pathways, some RISCs are able to directly target the genome by recruiting histone methyltransferases to form heterochromatin at the gene locus, 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.^[11][23][24] 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.^[25]

DNA elimination

The following RISC pathway is unique to Tetrahymena thermophila, which has two nuclei in its cell. One is a macronucleus, which is active during vegetative growth, whilst the other is a micronucleus, which is active during germ line. After sexual conjugation, a new macronucleus is formed from the mated micronucleus and the old macronucleus needs to be discarded. During the formation of the new macronucleus, parts of the DNA that were not present in the old macronucleus are eliminated by RISC. The proposed model is that the genetic content of the newly formed macronucleus is transcribed into siRNA, which is then loaded into RISCs as a template. RISCs then scan the old macronucleus, binding to any complementary region, and are discarded along with the old macronucleus. This leaves RISCs that did not bind to the old macronucleus and, therefore, only target unnecessary sequences in the new macronucleus, eliminating them so the new nucleus is identical to the old.^[11]

See also

• RNA-induced transcriptional silencing (RITS)
• RNA interference

Reference

1. Filipowicz W, Bhattacharyya SN, Sonenber N (2008). "Mechanisms of post-transcriptional regulation by microRNAs: are the answers in sight?". Nature Reviews Genetics. 9 (2): 102–114. doi:10.1038/nrg2290. PMID 18197166.
2. Fire A, Xu S, Montgomery MK, Kostas SA, Driver SE, Mello CC (1998). "Potent and specific genetic interference by double-stranded RNA in Caenorhabditis elegans". Nature. 391 (6669): 806–811. doi:10.1038/35888. PMID 9486653.
3. Watson, James D. (2008). Molecular Biology of the Gene. San Francisco, CA: Cold Spring Harbor Laboratory Press. pp. 641–648. ISBN 978-0-8053-9592-1.
4. Hammond SM, Bernstein E, Beach D, Hannon GJ (2000). "An RNA-directed nuclease mediates post-transcriptional gene silencing in Drosophila cells". Nature. 404 (6775): 293–296. doi:10.1038/35005107. PMID 10749213.
5. Sontheimer EJ (2005). "Assembly and function of RNA silencing complexes". Nature Reviews Molecular Cell Biology. 6 (2): 127–138. doi:10.1038/nrm1568.
6. Chendrimada TP, Gregory RI, Kumaraswamy E, Norman J, Cooch N, Nishikura K, Shiekhatter R (2005). "TRBP recruits the Dicer complex to Ago2 for microRNA processing and gene silencing". Nature. 436 (7051): 740–744. doi:10.1038/nature03868.
7. Wang HW, Noland C, Siridechadilok B, Taylor DW, Ma E, Felderer K, Doudna JA, Nogales E (2009). "Structural insights into RNA processing by the human RISC-loading complex". Nature Structural & Molecular Biology. 16 (11): 1148–1153. doi:10.1038/nsm.
8. Merritt WM, Bar-Eli M, Sood AK (Apr 2010). "The dicey role of Dicer: implications for RNAi therapy". Cancer Research. 70 (7): 2571–4. doi:10.1158/0008-5472.CAN-09-2536. PMC 3170915. PMID 20179193.
9. Hall TM (2005). "Structure and function of Argonaute proteins". Cell. 13 (10): 1403–1408. doi:10.1016/j.str.2005.08.005.
10. Meister G, Landthaler M, Patkaniowska A, Dorsett Y, Teng G, Tuschl T (2004). "Human Argonaute2 mediates RNA cleavage targeted by miRNAs and siRNAs". Molecular Cell. 15 (2): 1403–1408. doi:10.1016/j.molcel.2004.07.007. PMID 15260970.
11. Pratt AJ, MacRae IJ (2009). "The RNA-induced silencing complex: A versatile gene-silencing machine". Journal of Biological Chemistry. 284 (27): 17897–17901. doi:10.1074/jbc.R900012200. PMC 2709356. PMID 19342379. {{cite journal}}: Unknown parameter |lastauthoramp= ignored (|name-list-style= suggested) (help)
12. Lee HY, Zhou K, Smith AM, Doudna JA (2013). "Differential roles of human Dicer-binding proteins TRBP and PACT in small RNA processing". Nature. 41 (13). doi:10.1093/nar/gkt361. PMID 656876.
13. Zamore PD, Tuschl T, Sharp PA, Bartel DP (2000). "RNAi: double-stranded RNA directs the ATP-dependent cleavage of mRNA at 21 to 23 nucleotide intervals". Cell. 101 (1): 25–33. doi:10.1016/S0092-8674(00)80620-0. PMID 10778853.
14. Vermeulen A, Behlen L, Reynolds A, Wolfson A, Marshall W, Karpilow J, Khvorova A (2005). "The contributions of dsRNA structure to Dicer specificity and efficiency". RNA. 11 (5): 674–682. doi:10.1261/rna.7272305. PMC 1370754. PMID 15811921.
15. Schwarz DS, Hutvágner G, Du T, Xu Z, Aronin N, Zamore PD (2003). "Asymmetry in the assembly of the RNAi enzyme complex". Cell. 115 (2): 199–208. doi:10.1016/S0092-8674(03)00759-1. PMID 14567917.
16. Khvorova A, Reynolds A, Jayasena SD (2003). "Functional siRNAs and miRNAs exhibit strand bias". Cell. 115 (2): 209–216. doi:10.1016/S0092-8674(03)00801-8. PMID 14567918.
17. Siomi H, Siomi MC (2009). "On the road to reading the RNA-interference code". Nature. 457 (7228): 396–404. doi:10.1038/nature07754. PMID 19158785. {{cite journal}}: Unknown parameter |lastauthoramp= ignored (|name-list-style= suggested) (help)
18. Wakiyama M, Takimoto K, Ohara O, Yokoyama S (2007). "Let-7 microRNA-mediated mRNA deadenylation and translational repression in a mammalian cell-free system". Genes & Development. 21 (15): 1857–1862. doi:10.1101/gad.1566707. PMC 1935024. PMID 17671087.
19. Sen GL, Blau HM (2005). "Argonaute2/RISC resides in sites of mammalian mRNA decay known as cytoplasmic bodies". Nature Cell Biology. 7 (6): 633–636. doi:10.1038/ncb1265. PMID 15908945. {{cite journal}}: Unknown parameter |lastauthoramp= ignored (|name-list-style= suggested) (help)
20. Maroney PA, Yu Y, Fisher J, Nilsen TW (2006). "Evidence that microRNAs are associated with translating messenger RNAs in human cells". Nature Structural & Molecular Biology. 13 (12): 1102–1107. doi:10.1038/nsmb1174.
21. Petersen CP, Bordeleau ME, Pelletier J, Sharp PA (2006). "Short RNAs repress translation after initiation in mammalian cells". Molecular Cell. 21 (4): 533–542. doi:10.1016/j.molcel.2006.01.031. PMID 16483934.
22. Chendrimada TP, Finn KJ, Ji X, Baillat D, Gregory RI, Liebhaber SA, Pasquinelli AE, Shiekhattar R (2007). "MicroRNA silencing through RISC recruitment of eIF6". Nature. 447 (7146): 823–828. doi:10.1038/nature05841.
23. Verdel A, Jia S, Gerber S, Sugiyama T, Gygi S, Grewal SI, Moazed D (2004). "RNAi-mediated targeting of heterchromatin by the RITS complex". Science. 303 (5658): 672–676. doi:10.1126/science.1093686. PMC 3244756. PMID 14704433.
24. Verdel A, Jia S, Gerber S, Sugiyama T, Gygi S, Grewal SI, Moazed D (2004). "RITS acts in cis to promote RNA interference-mediated transcription and post-transcriptional silencing". Nature Genetics. 36 (11): 1174–1180. doi:10.1038/ng1452. PMID 15475954.
25. Sugiyama T, Cam H, Verdel A, Moazed D, Grewal SI (2005). "RNA-dependent RNA polymerase is an essential component of a self-enforcing loop coupling heterochromatin assembly to siRNA production". Proceedings of the National Academy of Sciences of the United States of America. 102 (1): 152–157. doi:10.1073/pnas.0407641102. PMC 544066. PMID 15615848.

Further reading

• Sontheimer, EJ (2005). "Assembly and function of RNA silencing complexes". Nature Reviews Molecular Cell Biology. 6 (2): 127–138. doi:10.1038/nrm1568.
• Fu, Q.; Yuan, Y. A. (2013). "Structural insights into RISC assembly facilitated by dsRNA-binding domains of human RNA helicase A (DHX9)". Nucleic Acids Research. 41 (5): 3457–3470. doi:10.1093/nar/gkt042. PMC 3597700. PMID 23361462.

External links

• Schwarz DS, Tomari Y, Zamore PD (2004). "The RNA-induced silencing complex is a Mg²⁺-dependent endonuclease". Current Biology. 14 (9): 787–91. doi:10.1016/j.cub.2004.03.008. PMID 15120070.
• Dcr-1 and Dcr-2 have distinct but overlapping roles in the siRNA and miRNA silencing pathways
• RNA-Induced+Silencing+Complex at the U.S. National Library of Medicine Medical Subject Headings (MeSH)
• RNAiAtlas - database of siRNA libraries and their target analysis results