Production of avian leukosis virus particles in mammalian cells can be mediated by the interaction of the human immunodeficiency virus protein Rev and the Rev-responsive element.

In human immunodeficiency virus type 1-infected cells, the efficient expression of viral proteins from unspliced and singly spliced RNAs is dependent on two factors: the presence in the cell of the viral protein Rev and the presence in the viral RNA of the Rev-responsive element (RRE). We show here that the HIV-1 Rev/RRE system can increase the expression of avian leukosis virus (ALV) structural proteins in mammalian cells (D-17 canine osteosarcoma) and promote the release of mature ALV virions from these cells. In this system, the Rev/RRE interaction appears to facilitate the export of full-length unspliced ALV RNA from the nucleus to the cytoplasm, allowing increased production of the ALV structural proteins. Gag protein is produced in the cytoplasm of the ALV-transfected cells even in the absence of a Rev/RRE interaction. However, a functional Rev/RRE interaction increases the amount of Gag present intracellularly and, more strikingly, results in the release of mature ALV particles into the supernatant. RCAS virus containing an RRE is replication-competent in chicken embryo fibroblasts; however, we have been unable to determine whether the particles produced in D-17 cells are as infectious as the particles produced in chicken embryo fibroblasts.     

Identification of a high-affinity RNA-binding site for the human immunodeficiency virus type 1 Rev protein.

Expression of the structural proteins of human immunodeficiency virus type 1 requires the direct interaction of multiple copies of the viral Rev protein with its highly structured RNA target sequence, the Rev response element (RRE). Nucleotides critical for Rev monomer binding have been mapped by chemical interference to a single site flanking the base of an RNA helix (stem IIB) located within the 234-nucleotide RRE. Binding of additional Rev molecules to an RRE probe did not require any RNA primary sequence information detectable by modification interference beyond that required for binding of a single Rev protein molecule. A synthetic 29-nucleotide RNA molecule designed to incorporate nucleotides identified as critical for Rev binding retained the ability to bind Rev specifically and, therefore, represents a minimal Rev-binding site. We propose that Rev binding to the RRE initiates with the direct interaction of a Rev monomer with a high-affinity binding site located at the base of the IIB stem of the RRE. The subsequent formation of Rev multimers on the RRE appears, in contrast, primarily driven by specific protein-protein interactions.     

A trans-dominant negative HIV type 1 Rev with intact domains of NLS/NOS and NES

The nuclear diffusion inhibitory signal (NIS) is a 15-amino acid peptide motif (10-24; EDLLKAVRLIKFLYQ) in the N-terminus of the HIV-1 Rev protein. NIS appears to be involved in maintaining the proper nucleocytoplasmic trafficking and intracellular stability of HIV-1 Rev. Deletion in NIS leads to Rev functional inactivity, and these data led to further investigation of its possible inhibitory effects on Rev function. An HIV-1 proviral rescue assay was utilized to evaluate Rev function. The association between wild-type Rev molecules, or wild-type Rev with Revd23, an NIS mutant, plus Rev-responsive element (RRE) interactions in cultured cells were also evaluated. Revd23 showed a potent trans-dominant negative phenotype, while multimerization with wild-type Rev and Revd23-RRE binding in cells were found to reveal no significant changes from wildtype. These results suggest that the potential trans-dominance mechanism of Revd23 may differ from that of a Rev construct, RevM10, with mutations in the C-terminus nuclear export signal (NES). As such, these data will be useful in the rational design of novel antiretroviral approaches targeting HIV-1 Rev.     

HIV Rev response element (RRE) directs assembly of the Rev homooligomer into discrete asymmetric complexes

RNA is a crucial structural component of many ribonucleoprotein (RNP) complexes, including the ribosome, spliceosome, and signal recognition particle, but the role of RNA in guiding complex formation is only beginning to be explored. In the case of HIV, viral replication requires assembly of an RNP composed of the Rev protein homooligomer and the Rev response element (RRE) RNA to mediate nuclear export of unspliced viral mRNAs. Assembly of the functional Rev-RRE complex proceeds by cooperative oligomerization of Rev on the RRE scaffold and utilizes both protein-protein and protein-RNA interactions to organize complexes with high specificity. The structures of the Rev protein and a peptide-RNA complex are known, but the complete RNP is not, making it unclear to what extent RNA defines the composition and architecture of Rev-RNA complexes. Here we show that the RRE controls the oligomeric state and solubility of Rev and guides its assembly into discrete Rev-RNA complexes. SAXS and EM data were used to derive a structural model of a Rev dimer bound to an essential RRE hairpin and to visualize the complete Rev-RRE RNP, demonstrating that RRE binding drives assembly of Rev homooligomers into asymmetric particles, reminiscent of the role of RNA in organizing more complex RNP machines, such as the ribosome, composed of many different protein subunits. Thus, the RRE is not simply a passive scaffold onto which proteins bind but instead actively defines the protein composition and organization of the RNP.     

Structural analysis of the interaction between the human immunodeficiency virus Rev protein and the Rev response element.

The specific interaction between a defined structural element of the human immunodeficiency virus mRNA (RRE, the Rev response element) and the virus-encoded protein Rev has been implicated in the regulation of the export of unspliced or singly spliced mRNA from the nucleus to the cytoplasm. Rev protein was expressed and purified from insect cells using the baculovirus expression system. Chemical and RNase probes were used to analyze the structure of the RRE and the regions involved in Rev binding. Increased reactivity to single-strand-specific probes of nucleotides in two helical domains indicates that Rev binding induces conformational changes in the RRE. Binding of Rev to the RRE primarily protects helical segments and adjacent nucleotides in domain II. A Rev unit binding site is proposed that consists of a six-base-pair helical segment and three adjacent nucleotides. The data also suggest that multiple Rev proteins bind to repeated structural elements of the RRE.     

HIV-1 Rev protein assembles on viral RNA one molecule at a time

Oligomerization of the HIV-1 protein Rev on the Rev Response Element (RRE) regulates nuclear export of genomic viral RNA and partially spliced viral mRNAs encoding for structural proteins. Single-molecule fluorescence spectroscopy has been used to dissect the multistep assembly pathway of this essential ribonucleoprotein, revealing dynamic intermediates and the mechanism of assembly. Assembly is initiated by binding of Rev to a high-affinity site in stem-loop IIB of the RRE and proceeds rapidly by addition of single Rev monomers, facilitated by cooperative Rev-Rev interactions on the RRE. Dwell-time analysis of fluorescence trajectories recorded during individual Rev-RRE assembly reactions has revealed the microscopic rate constants for several of the Rev monomer binding and dissociation steps. The high-affinity binding of multiple Rev monomers to the RRE is achieved on a much faster timescale than reported in previous bulk kinetic studies of Rev-RRE association, indicating that oligomerization is an early step in complex assembly.     

Inhibition of mRNA export in vertebrate cells by nuclear export signal conjugates

Leucine-rich nuclear export signals (NESs) are recognized by the NES receptor exportin 1 and are central to the export of multiple shuttling proteins and RNAs. The export of messenger RNA in vertebrates was, however, thought to occur by a different pathway, because inhibition by injection of a synthetic Rev NES conjugate could not be demonstrated. Here we find that peptide conjugates composed of the NES of either protein kinase A inhibitor protein (PKI) or the HIV-1 Rev protein, when coupled to human serum albumin, are potent inhibitors of mRNA and small nuclear RNA export. These results provide direct evidence that mRNA export in vertebrates depends on interactions between an NES and its cognate NES receptors. PKI NES conjugates are significantly more efficient at inhibiting RNA export than are REV NES conjugates, indicating that different NESs may have different abilities to promote protein and RNA export. Surprisingly, an expected control conjugate containing the mutant Rev NES sequence M10 strongly inhibited the export of intronless dihydrofolate reductase mRNA. Nuclear injection of NES peptide conjugates led to mislocalization to the nucleus of 10–20% of the cytoplasmic Ran GTPase-binding protein (RanBP1) indicating that RanBP1 shuttles between the nucleus and the cytoplasm via an NES pathway. These results demonstrate that in vertebrates the export of mRNA, like that of small nuclear RNA, 5S rRNA, and transport factors such as RanBP1, employs NES-mediated molecular machinery.     

Specific interaction of the human immunodeficiency virus Rev protein with a structured region in the env mRNA.

A region of potential complex secondary structure within the human immunodeficiency virus env mRNA has been implicated in Rev-mediated export of viral structural mRNAs from the nucleus to the cytoplasm. By using an RNase protection gel-mobility-shift assay, we demonstrate that purified Rev protein forms a stable complex with this Rev-responsive RNA. RNAs with mutations designed to disrupt formation of a predicted stem structure no longer interact with Rev. However, Rev binding is restored upon annealing of the two complementary RNAs that make up the stem. These results suggest that direct interaction of Rev with the Rev-responsive element could facilitate transport of human immunodeficiency virus structural mRNAs from the nucleus to the cytoplasm.     

A long-awaited structure is rev-ealed

It has been known for some time that the HIV Rev protein binds and oligomerizes on a well-defined multiple stem-loop RNA structure, named the Rev Response Element (RRE), which is present in a subset of HIV mRNAs. This binding is the first step in a pathway that overcomes a host restriction, which would otherwise prevent the export of these RNAs to the cytoplasm. Four recent publications now provide new insight into the structure of Rev and the multimeric RNA-protein complex that forms on the RRE [1–4]. Two unexpected and remarkable findings revealed in these studies are the flexibility of RNA binding that is demonstrated by the Rev arginine-rich RNA binding motif, and the way that both Rev protein and RRE contribute to the formation of the complex in a highly cooperative fashion. These studies also define the Rev dimerization and oligomerization interfaces to a resolution of 2.5Å, providing a framework necessary for further structural and functional studies. Additionally, and perhaps most importantly, they also pave the way for rational drug design, which may ultimately lead to new therapies to inhibit this essential HIV function.     

Encapsidation of Staufen-2 Enhances Infectivity of HIV-1

Staufen, the RNA-binding family of proteins, affects various steps in the Human Immuno-Deficiency Virus (HIV-1) replication cycle. While our previous study established Staufen-2–HIV-1 Rev interaction and its role in augmenting nucleocytoplasmic export of RRE-containing viral RNA, viral incorporation of Staufen-2 and its effect on viral propagation were unknown. Here, we report that Staufen-2 interacts with HIV-1 Gag and is incorporated into virions and that encapsidated Staufen-2 boosted viral infectivity. Further, Staufen-2 gets co-packaged into virions, possibly by interacting with host factors Staufen-1 or antiviral protein APOBEC3G, which resulted in different outcomes on the infectivity of Staufen-2-encapsidated virions. These observations suggest that encapsidated host factors influence viral population dynamics and infectivity. With the explicit identification of the incorporation of Staufen proteins into HIV-1 and other retroviruses, such as Simian Immunodeficiency Virus (SIV), we propose that packaging of RNA binding proteins, such as Staufen, in budding virions of retroviruses is probably a general phenomenon that can drive or impact the viral population dynamics, infectivity, and evolution.     

The HIV 5′ Gag Region Displays a Specific Nucleotide Bias Regulating Viral Splicing and Infectivity

Alternative splicing and the expression of intron-containing mRNAs is one hallmark of HIV gene expression. To facilitate the otherwise hampered nuclear export of non-fully processed mRNAs, HIV encodes the Rev protein, which recognizes its intronic response element and fuels the HIV RNAs into the CRM-1-dependent nuclear protein export pathway. Both alternative splicing and Rev-dependency are regulated by the primary HIV RNA sequence. Here, we show that these processes are extremely sensitive to sequence alterations in the 5’coding region of the HIV genomic RNA. Increasing the GC content by insertion of either GFP or silent mutations activates a cryptic splice donor site in gag, entirely deregulates the viral splicing pattern, and lowers infectivity. Interestingly, an adaptation of the inserted GFP sequence toward an HIV-like nucleotide bias reversed these phenotypes completely. Of note, the adaptation yielded completely different primary sequences although encoding the same amino acids. Thus, the phenotypes solely depend on the nucleotide composition of the two GFP versions. This is a strong indication of an HIV-specific mRNP code in the 5′ gag region wherein the primary RNA sequence bias creates motifs for RNA-binding proteins and controls the fate of the HIV-RNA in terms of viral gene expression and infectivity.     

The Rex regulatory protein of human T-cell lymphotropic virus type I binds specifically to its target site within the viral RNA.

The Rex protein of human T-cell leukemia virus type I (HTLV-I) was expressed in bacteria and partially purified. Rex was shown to bind in vitro specifically to an RNA sequence located in the 3' long terminal repeat of HTLV-I, named Rex-responsive element (RXRE). Rex also bound in vitro to the human immunodeficiency virus type 1 (HIV-1) Rev-responsive element (RRE), while purified HIV-1 Rev protein did not bind to the RXRE. The binding results obtained in vitro are therefore in agreement with the nonreciprocal function of Rev and Rex in vivo. Rex binds specifically to both RRE and RXRE and activates expression in both HIV-1 and HTLV-I, while Rev binds to RRE and activates only HIV-1. Binding of Rex to RRE deletion mutants previously shown to lack either the Rev-responsive or the Rex-responsive portion suggested preferential binding of Rex to a distinct target within the RRE. These results demonstrated that Rex, like Rev, acts by binding to a specific RNA target.     

Nuclear export of late HIV-1 mRNAs occurs via a cellular protein export pathway.

The Rev protein of HIV-1 is essential for the nuclear export of incompletely spliced viral mRNAs. This action depends on the mutationally defined Rev activation domain, which both binds the nucleoporin-like human cellular cofactor Rab/hRIP and also functions as a nuclear export signal. Protein kinase inhibitor alpha (PKI) also contains a potent nuclear export signal. However, PKI plays no role in nuclear RNA export and instead induces the nuclear export of a specific protein target, the catalytic subunit of cAMP-dependent protein kinase. Here, it is demonstrated that the nuclear export signal of PKI not only binds the Rab/hRIP cofactor specifically but also can effectively substitute for the Rev activation domain in mediating the nuclear export of HIV-1 mRNAs. We conclude that HIV-1 Rev and PKI act through an identical nuclear export pathway and that Rev, rather than using a dedicated RNA export pathway, is instead acting as an adaptor that allows viral mRNAs to access a cellular protein export pathway.     

Enhanced T cell engraftment after retroviral delivery of an antiviral gene in HIV-infected individuals

Intracellular expression of gene products that inhibit viral replication have the potential to complement current antiviral approaches to the treatment of AIDS. We previously have shown that a mutant inhibitory form of an essential viral protein, Rev M10, prolongs the survival of T cells transduced with a nonviral vector in HIV-infected individuals. Because these gene-modified cells were not observed in patients beyond 8 weeks, efforts were made to improve the duration of engraftment. In this study, we used retroviral vector delivery of Rev M10 to CD4⁺ cells and analyzed relevant immune responses in a pilot study of three HIV-seropositive patients. DNA and RNA PCR analyses revealed that cells transduced with Rev M10 retroviral vectors survived and expressed the recombinant gene for significantly longer time periods than those transduced with a negative control vector in all three patients. Immune responses were not detected either to Rev M10 or to Moloney murine leukemia virus gp70 envelope protein. Rev M10-transduced cells were detected for an average of 6 months after retroviral gene transfer compared with ≈3 weeks for the previously reported nonviral vector delivery. These findings suggest that retroviral delivery of an antiviral gene may potentially contribute to immune reconstitution in AIDS and could provide a more effective vector to prolong survival of CD4⁺ cells in HIVinfection.     

The type I human T-cell leukemia virus (HTLV-I) Rex trans-activator binds directly to the HTLV-I Rex and the type 1 human immunodeficiency virus Rev RNA response elements.

The Rex protein of the type I human T-cell leukemia virus (HTLV-I) is essential for the replication of this pathogenic retrovirus and, surprisingly, can also replace the function of the structurally distinct Rev protein of the type 1 human immunodeficiency virus (HIV-1). Rex action requires a 255-nucleotide viral RNA stem-loop structure termed the Rex RNA response element (RexRE) located in the 3' retroviral long terminal repeat. Rex function leads to the induced cytoplasmic expression of the incompletely spliced family of viral mRNAs that uniquely encode the HTLV-I structural and enzymatic proteins (Gag, Pol, and Env). Our studies now demonstrate that Rex acts by binding directly to the RexRE in a sequence-specific manner. These effects of Rex require the presence of a 10-nucleotide subregion of the RexRE that is essential for Rex function in vivo. Dominant-negative mutants of Rex also bind to the RexRE with high affinity, while a recessive-negative Rex mutant altered within its arginine-rich, positively charged domain fails to engage the RexRE. Analogously, both the wild-type and dominant-negative Rex proteins specifically bind to the structurally distinct HIV-1 Rev response element, a finding that likely underlies the respective stimulatory and inhibitory effects of these HTLV-I proteins in the heterologous HIV-1 system. However, consistent with their lack of amino acid homology, the binding sites for Rex and Rev within the HIV-1 Rev response element are distinct.     

A small element from the Mason-Pfizer monkey virus genome makes human immunodeficiency virus type 1 expression and replication Rev-independent.

Replication of human immunodeficiency virus type 1(HIV-1) is dependent on the viral Rev protein. This protein acts in concert withthe cis-acting rev-responsive element present in intron-containing RNAs tofacilitate nuclear export of these RNAs. Here we show that a cis-acting219-nucleotide sequence from an unrelated "simple" retrovirus,Mason-Pfizer monkey virus (MPMV), enables Rev-independent HIV-1 replication.This sequence is present in an untranslated region near the 3' end of theMPMV genome. The MPMV element is also able to efficiently substitute for Rev inexpression of Gag/Pol and Env proteins from subgenomic constructs. Wehypothesize that the MPMV element functions by interacting with a cellularfactor that plays a role in mRNA transport analogous to that of the Rev protein.It might be possible to exploit this element in the development of an HIVvaccine.