Phenotypic analysis of human immunodeficiency virus type 1 Rev trimerization-interface mutants in human cells

Trikha, Roochi; Brighty, David W.

doi:10.1099/vir.0.80572-0

Cited by 4 publications

(6 citation statements)

References 15 publications

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“…Additionally, the lateral position for L18 may explain its putative role in HIV-1 latency by slightly hindering Rev oligomerization, which in turn reduces Rev function, leading to less Gag expression and greater possibility for infected cells to escape anti-Gag cytotoxic T-cell responses. Mutations of the polar residues Y23, S25, and N26 disrupt oligomerization, resulting in an increased cytoplasmic concentration of Rev (2,24,25). Y23 makes significant contacts both within the Rev monomer and at the A-A interface, explaining the functional phenotype; S25 and N26 are on the B-surface and so support the imputed role of this surface in Rev oligomerization.…”

Section: Resultsmentioning

confidence: 99%

Implications of the HIV-1 Rev dimer structure at 3.2 Å resolution for multimeric binding to the Rev response element

DiMattia

Watts²,

Stahl³

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

119

180

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HIV-1 Rev is a small regulatory protein that mediates the nuclear export of viral mRNAs, an essential step in the HIV replication cycle. In this process Rev oligomerizes in association with a highly structured RNA motif, the Rev response element. Crystallographic studies of Rev have been hampered by the protein's tendency to aggregate, but Rev has now been found to form a stable soluble equimolar complex with a specifically engineered monoclonal Fab fragment. We have determined the structure of this complex at 3.2 Å resolution. It reveals a molecular dimer of Rev, bound on either side by a Fab, where the ordered portion of each Rev monomer (residues 9-65) contains two coplanar α-helices arranged in hairpin fashion. Subunits dimerize through overlapping of the hairpin prongs. Mating of hydrophobic patches on the outer surface of the dimer is likely to promote higher order interactions, suggesting a model for Rev oligomerization onto the viral RNA.nuclear export | ribonucleoprotein structure | Fab cocrystallization | posttranscriptional regulation | crystal structure T he unspliced and partially spliced viral mRNAs whose nuclear export is promoted by the 13 kDa HIV-1 Rev protein (1, 2) are used both as genomic RNA for packaging into assembling virions and for translation of many of the viral proteins (3), thereby eliciting the transition from early to late phase infection (1). Rev targets viral mRNAs by recognizing a ∼350 nt, highly structured region within an env intron known as the Rev response element (RRE) (4). Rev then oligomerizes onto the RRE to form a ribonucleoprotein (RNP) complex of 200-300 kDa containing 8-10 Rev molecules (5, 6) that binds Crm-1 (exportin-1), GTP-bound Ran, and other host cell proteins via the Rev nuclear export sequence (NES), to promote nuclear export (7). Rev contains an arginine-rich RNA-binding motif (ARM) that specifically binds to a purine-rich bulge within stem loop IIb of the RRE (2, 8) with high affinity to nucleate assembly of the Rev-RRE complex (9, 10). Subsequently, 7-9 additional Rev molecules are recruited (4-6, 11), one at a time, in a highly cooperative process mediated primarily through Rev-Rev interactions (5,(12)(13)(14). As befits their biological importance, the interactions whereby Rev recognizes RRE-containing RNAs have been intensively studied, as has Rev's propensity to oligomerize, both in the absence of RNA and in the context of the RRE (9, 10, 15, 16).Knowledge of Rev structure is essential to understanding its cooperative binding to the RRE and for the development of antiviral drugs that interfere with Rev's essential functions. So far, detailed structural information has been limited to an NMR structure of a 22-residue synthetic polypeptide corresponding to the ARM in complex with stem loop IIb (8). Rev's propensity to oligomerize into filaments (16) has hindered crystallization. Using a Fab engineered to inhibit Rev polymerization, we have been able to purify and crystallize a Rev-Fab complex (17). Here we report the structure determination of this com...

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Section: Resultsmentioning

confidence: 99%

Implications of the HIV-1 Rev dimer structure at 3.2 Å resolution for multimeric binding to the Rev response element

DiMattia

Watts²,

Stahl³

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

119

180

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“…Shuttling Rev between the cytoplasm and the nucleus requires an interaction between unbound Rev and importins such as importin β, as well as an interaction between Rev–RNA complexes and the export receptor Crm‐1 (Pollard and Malim 1998). Both L60R and M4‐Rev with mutations to positions 23, 25, and 26 (Malim et al 1989b) show an increased presence in the cytoplasm relative to wild type (Szilvay et al 1997; Trikha and Brighty 2005). This pattern of cytoplasmic localization has been cited as evidence for an oligomerization requirement for nuclear import (Trikha and Brighty 2005).…”

Section: Discussionmentioning

confidence: 99%

“…Both L60R and M4‐Rev with mutations to positions 23, 25, and 26 (Malim et al 1989b) show an increased presence in the cytoplasm relative to wild type (Szilvay et al 1997; Trikha and Brighty 2005). This pattern of cytoplasmic localization has been cited as evidence for an oligomerization requirement for nuclear import (Trikha and Brighty 2005). Cytoplasmic accumulation of Rev also results from increasing the rate of Rev export (Soros and Cochrane 2001).…”

Section: Discussionmentioning

confidence: 99%

“…In the previous study by Jain and Belasco (2001), the behavior of Rev mutations that disrupt oligomeric binding on the RRE was used to support a model of oligomerization wherein a helix‐turn‐helix motif undergoes oligomerization into groups of four‐helix bundles. Their work was based on studies of Rev mutants that have established Rev oligomerization on the RRE as a prerequisite for export activity (Malim and Cullen 1991) and that have been used to map the Rev oligomerization interfaces (Malim and Cullen 1991; Thomas et al 1997, 1998; Trikha and Brighty 2005). However, because the relationship between oligomeric binding and RNA‐free Rev was untested and because equal changes in oligomerization have been related to different effects on trans ‐activation (Thomas et al 1997; Brice et al 1999; Trikha and Brighty 2005; Churchill et al 2007), further investigation of the Jain and Belasco (2001) model was warranted.…”

Section: Discussionmentioning

confidence: 99%

“…Understanding the essential contribution made by Rev oligomerization to influence the course of the viral infection (Malim and Cullen 1991; Madore et al 1994; Mann et al 1994) has been hampered by the resulting lack of detailed structural information on the oligomeric complexes. Many questions concerning the connection between Rev structure and oligomeric Rev–RRE assembly (Blanco et al 2001; Havlin et al 2007), the self‐association tendency of Rev in the absence of its cognate RRE (Wingfield et al 1991; Cole et al 1993; Havlin et al 2007), and the observation of Rev variants with similar assembly properties on the RNA but profoundly different levels of trans ‐activation activity (Thomas et al 1997; Brice et al 1999; Trikha and Brighty 2005; Churchill et al 2007) remain to be answered.…”

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confidence: 99%

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Protein structure and oligomerization are important for the formation of export‐competent HIV‐1 Rev–RRE complexes

et al. 2008

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The translation of the unspliced and partially spliced viral mRNAs that encode the late, structural proteins of HIV-1 depends on the viral-protein Rev. Oligomeric binding of Rev to the Rev response element (RRE) in these mRNAs promotes their export from the nucleus and thus controls their expression. Here, we compared the effects of hydrophobic to hydrophilic mutations within the oligomerization domain of Rev using assays for oligomeric RNA binding, protein structure, and export from the nucleus. Oligomeric RNA binding alone does not correlate well with RNA transport activity in the subset of mutants. However, protein structure as judged by CD spectroscopy does correlate well with Rev function. The oligomeric assembly of Rev-L18T is impaired but exhibits minor defects in structure and retains a basal level of activity in vivo. The prevalence of L18T in infected individuals suggests a positive selection mechanism for L18T modulation of Rev activity that may delay the onset of AIDS.Keywords: HIV-1; Rev; RRE; nuclear export; viral latencyThe Rev protein of HIV-1 controls gene expression by promoting the nuclear export of unspliced and partially spliced viral mRNA (Malim et al. 1989b;Pollard and Malim 1998;Hope 1999). Rev recognizes these mRNAs through both the binding of an arginine-rich RNA binding domain (RBD) to a specific binding site within the Rev response element (RRE) (Malim et al. 1989a;Bogerd and Greene 1993) and the self-association of Rev monomers into higher-order oligomeric complexes on the RRE (Malim et al. 1989a;Bogerd and Greene 1993). It is this strong tendency to self-associate that has thwarted attempts to obtain structural information of full-length Rev at the atomic level. Understanding the essential contribution made by Rev oligomerization to influence the course of the viral infection (Malim and Cullen 1991;Madore et al. 1994;Mann et al. 1994) has been hampered by the resulting lack of detailed structural information on the oligomeric complexes. Many questions concerning the connection between Rev structure and oligomeric Rev-RRE assembly (Blanco et al. 2001;Havlin et al. 2007), the self-association tendency of Rev in the absence of its cognate RRE (Wingfield et al. 1991;Cole et al. 1993;Havlin et al. 2007), and the observation of Rev variants with

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DDX1 Is an RNA-Dependent ATPase Involved in HIV-1 Rev Function and Virus Replication

Edgcomb

Carmel

Naji

et al. 2012

Journal of Molecular Biology

102

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The HIV-1 Rev protein is essential for the virus because it promotes nuclear export of alternatively-processed mRNAs, and Rev is also linked to translation of viral mRNAs and genome encapsidation. Previously, the human DEAD-box helicase DDX1 was suggested to be involved in Rev functions, but this relationship is not well understood. Biochemical studies of DDX1 and its interactions with Rev and model RNA oligonucleotides were carried out to investigate the molecular basis for association of these components. A combination of gel-filtration chromatography and circular dichroism spectroscopy demonstrated that recombinant DDX1 expressed in E. coli is a well-behaved folded protein. Binding assays using fluorescently-labeled Rev and cell-based immunoprecipitation analysis confirmed a specific RNA-independent DDX1-Rev interaction. Additionally, DDX1 was shown to be an RNA-activated ATPase, wherein Rev-bound RNA was equally effective at stimulating ATPase activity as protein-free RNA. Gel mobility shift assays further demonstrated that DDX1 forms complexes with Rev-bound RNA. RNA silencing of DDX1 provided strong evidence that DDX1 is required for both Rev activity and HIV production from infected cells. Collectively, these studies demonstrate a clear link between DDX1 and HIV-1 Rev in cell based assays of HIV-1 production, and provide the first demonstration that recombinant DDX1 binds Rev and RNA, and has RNA dependent catalytic activity.

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Phenotypic analysis of human immunodeficiency virus type 1 Rev trimerization-interface mutants in human cells

Cited by 4 publications

References 15 publications

Implications of the HIV-1 Rev dimer structure at 3.2 Å resolution for multimeric binding to the Rev response element

Implications of the HIV-1 Rev dimer structure at 3.2 Å resolution for multimeric binding to the Rev response element

Protein structure and oligomerization are important for the formation of export‐competent HIV‐1 Rev–RRE complexes

DDX1 Is an RNA-Dependent ATPase Involved in HIV-1 Rev Function and Virus Replication

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