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HIV Rev response element

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The HIV-1 Rev response element (RRE) is a highly structured, ~350 nucleotide RNA segment present in the Env coding region of unspliced and partially spliced viral mRNAs. In the presence of the HIV-1 accessory protein Rev, HIV-1 mRNAs that contain the RRE can be exported from the nucleus to the cytoplasm for downstream events such as translation and virion packaging.[1][2]

RRE Location in the HIV-1 Genome. RRE is located within the Env coding region of HIV-1.

RRE and HIV-1 biology

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Early phase

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HIV-1 RNA export. In the early phase (top), transcribed viral RNAs (9kb) are spliced down to 2kb before export. One of these 2kb messages is translated to produce Rev which is then imported into the nucleus. In the late phase (bottom), Rev binds the RRE of newly transcribed RNAs before splicing and exports the unspliced (9kb) and partially spliced (4kb) messages to the cytoplasm. Translation of these messages produces late stage viral proteins. 9 kb messages can also serve as genomes for new virions.

The HIV-1 genome contains a single promoter and uses multiple reading frames and alternative splicing to encode 15 proteins from a single pre-mRNA species.[3] Transcription from an integrated HIV-1 provirus generates a single 9 kilobase (kb) pre-mRNA containing multiple splice sites and nuclear retention signals. In the early phase of the viral life cycle, this pre-RNA is completely spliced to RRE-free, 2 kb messages. These smaller messages are then transported from the nucleus to the cytoplasm via standard mRNA nuclear export pathways [4] (see Figure). One of these small, 2kb messages encodes the HIV-1 Rev protein which is imported into the nucleus via its nuclear localization sequence. This phase of the virus life cycle is both Rev and RRE independent.[2]

Late phase

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The late phase of the viral life cycle is characterized by the expression of viral proteins that are encoded on the long, unspliced (9kb) or partially spliced (4 kb) messages containing the RRE. Because of their retention and splicing signals, these intron-containing RNAs are initially retained in the nucleus for splicing/degradation. However, after a sufficient level of Rev has been produced by the 2 kb messages, these longer messages can be exported to the cytoplasm via a Rev dependent export pathway. Nuclear export of these RNAs is achieved by a specific, co-operative assembly of multiple Rev molecules on the RRE. Assembly of this Rev-RRE complex is followed by the recruitment of a human protein complex containing the proteins exportin-1 (XPO1/CRM1) and Ran-GTP. Rev recruits this export machinery via a nuclear export sequence (NES) present in Rev. This Rev-RRE-Xpo1/RanGTP complex is then transported to the cytoplasm. In the cytoplasm, these messages are translated to produce all the remaining viral proteins or packaged as genomes for newly budding virions (see Figure).[2]

Secondary Structure and Rev Recognition

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The RRE is a highly structured RNA element. Computational predictions, later verified by chemical and enzymatic probing, indicate that RRE contains multiple stem loops and bulges (see Figure). Rev binds to RRE in a sequence specific manner with Rev-RNA recognition mediated by a 17-residue a-helical stretch on Rev, the Arginine-Rich-Motif (ARM).

RRE Secondary Structure. Secondary Structure of the minimal functional RRE (~250 nt). The RRE contains several stem loops, the most well characterized being the high affinity binding site, IIB. IIB is necessary but not sufficient for RRE mediated export. Stem IA is a more recently identified, secondary binding site. The remaining binding sites on the RRE have not been characterized yet.

Stem IIB: a high-affinity binding site

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Stem IIB is a site on the RRE which Rev binds with high affinity and specificity. The structure of an isolated stem IIB bound to a peptide corresponding to a Rev-ARM has been solved by NMR.[5] This structure reveals an RNA A-form major groove widened by purine-purine base pairs at the purine-rich bulge to accommodate the a-helical Rev-ARM. Binding is achieved through a combination of base-specific contacts and electrostatic contacts with the phosphate backbone (see figure). More recent studies have identified another region on the RRE, stem IA, that binds Rev in a specific manner, but with a 5-fold weaker affinity than stem IIB.[6]

Rev-ARM/IIB structure. (Left) Stem IIB RNA(red) A-‐form major groove cradling the Rev-‐ARM α-‐helix (blue). The Rev-ARM is a short peptide that represents the RNA binding domain of Rev. (Right) A rotated view showing the purine-‐purine base pairs (yellow) that widen the RNA major groove.

Co-operative Rev assembly required for RRE function

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Although Stems IIB and IA can bind Rev in isolation, a full-length RRE (at least ~250 nt) is required for viral function. Multiple molecules of Rev bind to the full RRE in a specific and co-operative manner through a combination of Rev-RNA and Rev-Rev interactions.[6][7][8] It is believed that IIB acts as an "anchor point", with the Rev molecules bound at secondary sites (such as IA) stabilized by protein-protein interactions with other Rev molecules (in addition to the RNA-protein interactions). Biochemical studies on a 242-nucleotide RRE have established a ratio of 6 Rev monomers to each RRE.[9]

In a sense, the RRE acts as a scaffolding platform onto which a specific and co-operative complex of Revs (and eventually cellular export machinery) assembles. This cooperativity that is dictated by RRE structure and sequence is required for the formation of a high affinity, export-competent complex.[10] Current models of Rev assembly on the RRE suggest an initial Rev nucleation event at stem IIB followed by progressive addition of Rev molecules to form the full complex.[7][8][11][12]

Rev-RRE Complexes recruit additional partners

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After assembly of a Rev-RRE complex, cellular export machinery must be added to guide the RNA through the nuclear pore. Nuclear export of Rev-RRE containing mRNAs is achieved using the human Crm1-RanGTP nuclear export pathway. Rev contains a nuclear export sequence (NES) that binds Crm1,[13][14] and Crm1 guides the entire complex out of the nucleus.

Recent crystal structures of Rev,[15][16] the Rev-ARM/Stem IIB structure and the information on Rev-RRE stoichiometry have led to the proposal of a jelly-fish model for a functionally active complex. In this model, The RRE provides a structural scaffold to assemble a Rev hexamer, and this assembly forms the head of the jelly-fish. The NESs from the 6 Rev monomers form the jelly-fish "tentacles" that could interact with the host Crm1-RanGTP proteins.[15] This entire "jellyfish" would then be exported to the cytoplasm (see Figure).

Jellyfish model of Rev/RRE assembly. This is a schematic representation of how an export-competent Rev–RRE complex might form: Rev molecules assemble onto the RRE scaffold to form an oligomeric assembly. In the “jellyfish” model, the jellyfish head comprises Rev oligomers and RRE; the Rev–NESs form the "tentacles" that interact with Crm1 (shown in the space-filled model) making the complex ready for export.

Tertiary structure

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Images of the tertiary structure of RRE (and the Rev-RRE complex) have been captured using atomic force microscopy.[17] These images show a globular "head" with a long stalk extending from it and are in accordance with 3D predictions from computer models, as well as electron microscope (EM) images of assembled Rev-RRE complexes.[15]

Rev-RRE as a Drug Target

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As the export of RRE-containing RNAs is essential for HIV replication, the association of RRE and Rev is an attractive therapeutic target.[18] Various RNA cleavage methods and small molecule screens[19] have been implemented in an effort to design antiviral drugs to treat HIV infection by metallopeptide structures.[18][20] Rev and RRE are particularly attractive drug targets as both elements exist in reading frames that code other proteins (Tat and Env for Rev, Env for RRE), theoretically restricting potential escape mutations. However, to date there are no clinically approved therapies that target Rev-RRE.

Relationship to Other Viruses

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All complex retroviruses face the problem of exporting unspliced and partially spliced mRNAs. Some use systems similar to Rev/RRE; these include HIV-2 and SIV (Simian Immunodeficiency Virus) which use their own Rev-RRE systems, some betaretroviruses, which use a Rem/RmRE system, and all deltaretroviruses which use a Rex/RxRRE systems.[21][22]

Many simple retroviruses, most notably Mason–Pfizer monkey virus (MPMV), do not encode a Rev-like protein, but instead have evolved a cis-acting RNA element, the constitutive transport element (CTE), that directly binds to components of the host mRNA export machinery. The MPMV CTE is ~220 nucleotides and consists of two identical binding sites for the cellular export protein Tap. Tap directly binds the viral RNA and exports it to the cytoplasm.[23][24]

See also

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References

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  12. ^ Pond, S. J. K.; Ridgeway, W. K.; Robertson, R.; Wang, J.; Millar, D. P. (2009). "HIV-1 Rev protein assembles on viral RNA one molecule at a time". Proceedings of the National Academy of Sciences. 106 (5): 1404–1408. doi:10.1073/pnas.0807388106. PMC 2635779. PMID 19164515.
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  14. ^ Fornerod, Maarten; Ohno, Mutsuhito; Yoshida, Minoru; Mattaj, Iain W. (1997). "CRM1 Is an Export Receptor for Leucine-Rich Nuclear Export Signals". Cell. 90 (6): 1051–1060. doi:10.1016/S0092-8674(00)80371-2. PMID 9323133.
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  17. ^ Pallesen, Jesper; Dong, Mingdong; Besenbacher, Flemming; Kjems, JøRgen (2009). "Structure of the HIV-1 Rev response element alone and in complex with regulator of virion (rev) studied by atomic force microscopy". FEBS Journal. 276 (15): 4223–4232. doi:10.1111/j.1742-4658.2009.07130.x. PMID 19583776.
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  19. ^ Shuck-Lee, D.; Chen, F. F.; Willard, R.; Raman, S.; Ptak, R.; Hammarskjold, M.-L.; Rekosh, D. (2008). "Heterocyclic Compounds That Inhibit Rev-RRE Function and Human Immunodeficiency Virus Type 1 Replication". Antimicrobial Agents and Chemotherapy. 52 (9): 3169–3179. doi:10.1128/AAC.00274-08. PMC 2533482. PMID 18625767.
  20. ^ Jin, Yan; Cowan, J. A. (2006). "Targeted Cleavage of HIV Rev Response Element RNA by Metallopeptide Complexes". Journal of the American Chemical Society. 128 (2): 410–411. doi:10.1021/ja055272m. PMID 16402818.
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  24. ^ Braun, I. C.; Rohrbach, E; Schmitt, C; Izaurralde, E (1999). "TAP binds to the constitutive transport element (CTE) through a novel RNA-binding motif that is sufficient to promote CTE-dependent RNA export from the nucleus". The EMBO Journal. 18 (7): 1953–1965. doi:10.1093/emboj/18.7.1953. PMC 1171280. PMID 10202158.
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