Detection of Rev peptides with impedance-sensors--comparison of device-geometries.

Two different impedance-sensor geometries have been compared for the detection of Rev peptides with a molecular weight of 2.4 kDa. Planar, two-dimensional interdigitated capacitor (IDC) sensors with electrode separations of 1.1 microm as well as three-dimensional nanogap-sensors with an electrode separation of 75 nm have been used. Both sensors have been operated at a fixed frequency of 980 MHz. We discuss the specific interaction of the Rev peptide to an immobilized RNA anti-Rev aptamer (9.2 kDa) for peptide concentrations in the range of 100 nM-2 microM. For the IDC sensor, only peptide concentrations above 500 nM gave detectable signals. For the nanogap sensor, the binding process was clearly visible for all concentrations applied. The higher sensitivity of the nanogap compared to the IDC is ascribed to the improved surface-to-volume ratio.

Structural constraints and mutational bias in the evolutionary restoration of a severe deletion in RNA phage MS2.

A 4-nucleotide (nt) deletion was made in the 36-nt-long intercistronic region separating the coat and replicase genes of the single-stranded RNA phage MS2. This region is the focus of several RNA structures conferring high fitness. One such element is the operator hairpin, which, in the course of infection, will bind a coat-protein dimer, thereby precluding further replicase synthesis and initiating encapsidation. Another structure is a long-distance base pairing (MJ) controlling replicase expression. The 4-nt deletion does not directly affect the operator hairpin but it disrupts the MJ pairing. Its main effect, however, is a frame shift in the overlapping lysis gene. This gene starts in the upstream coat gene, runs through the 36-nt-long intercistronic region, and ends in the downstream replicase cistron. Here we report and interpret the spectrum of solutions that emerges when the crippled phage is evolved. Four different solutions were obtained by sequencing 40 plaques. Three had cured the frame shift in the lysis gene by inserting one nt in the loop of the operator hairpin causing its inactivation. Yet these low-fitness revertants could further improve themselves when evolved. The inactivated operator was replaced by a substitute and thereafter these revertants found several ways to restore control over the replicase gene. To allow for the evolutionary enrichment of low-probability but high-fitness revertants, we passaged lysate samples before plating. Revertants obtained in this way also restored the frame shift, but not at the expense of the operator. By taking larger and larger lysates samples for such bulk evolution, ever higher-fitness and lower-frequency revertants surfaced. Only one made it back to wild type. As a rule, however, revertants moved further and further away from the wild-type sequence because restorative mutations are, in the majority of cases, selected for their capacity to improve the phenotype by optimizing one of several potential alternative RNA foldings that emerge as a result of the initial deletion. This illustrates the role of structural constraints which limit the path of subsequent restorative mutations.

HIV Rev self-assembly is linked to a molten-globule to compact structural transition.

By regulating the differential expression of proviral pre mRNA in the host cell, Rev plays a crucial role in the HIV-1 life cycle. The capacity of Rev to function is intimately linked to its ability to self-associate. Nevertheless, little is known about the exact role of self-association in the molecular mechanism defining its biological activity. A prerequisite knowledge is a definition of the molecular events undertaken by Rev during the process of self-assembly. Thus, this study was initiated to monitor the structure of Rev as a function of protein concentration. Rev undergoes a structural transition as a consequence of self-assembly. This structural transition was monitored by three spectroscopic methods. The accessibility of the single tryptophan in Rev monomer to acrylamide quenching increases with decreasing protein concentration. At very low concentration of Rev, the tryptophan accessibility is close to that of an unfolded Rev. As evaluated by circular dichroism, the secondary structure of Rev is protein concentration dependent as evidenced by an increase in the magnitude of ellipticity with increasing protein concentration. Further, results from ANS binding studies indicate that the ANS binding sites in Rev experience an apparent increase in hydrophobicity as the Rev concentration was increased. These concentration dependent changes seem to reach a maximum above 5 microM Rev monomer concentration. In order to define the mode of Rev self-association sedimentation velocity and equilibrium experiments were conducted. There are evidently two consecutive progressive association processes. At protein concentrations below 0.5 mg/ml, the data from sedimentation studies can be fitted to a single isodesmic model. Simulation of velocity sedimentation profile indicates that free Rev monomer that has not entered into the association processes can best be described to exhibit a value of S(20,w) that is substantially smaller than 1.4 S, a value needed to fit the rest of the data. The latter value is consistent for a Rev monomer with the expected molecules weight and if it were to assume a compact globular shape. These spectroscopic and hydrodynamic results imply that monomeric Rev is in a molten globule state, which becomes more compact upon self-association.

Using in vitro selection to direct the covalent attachment of human immunodeficiency virus type 1 Rev protein to high-affinity RNA ligands.

We have used an in vitro selection procedure called crosslinking SELEX (SELEX = systematic evolution of ligands by exponential enrichment) to identify RNA sequences that bind with high affinity and crosslink to the Rev protein from human immunodeficiency virus type 1 (HIV-1). A randomized RNA library substituted with the photoreactive chromophore 5-iodouracil was irradiated with monochromatic UV light in the presence of Rev. Those sequences with the ability to photocrosslink to Rev were partitioned from the rest of the RNA pool, amplified, and used for the next round of selection. Rounds of photocrosslinking selection were alternated with rounds of selection for RNA sequences with high affinity to Rev. This iterative, dual-selection method yielded RNA molecules with subnanomolar dissociation constants and high efficiency photocrosslinking to Rev. Some of the RNA molecules isolated by this procedure form a stable complex with Rev that is resistant to denaturing gel electrophoresis in the absence of UV irradiation. In vitro selection of nucleic acids by using modified nucleotides allows the isolation of nucleic acid molecules with potentially limitless chemical capacities to covalently attack a target molecule.

Binding of human prothymosin alpha to the leucine-motif/activation domains of HTLV-I Rex and HIV-1 Rev.

Rex of human T-cell leukemia virus type I (HTLV-I) and Rev of human immunodeficiency virus 1 (HIV-1) are post-transcriptional regulators of viral gene expression. By means of affinity chromatography, we purified an 18-kDa cellular protein that bound to the conserved leucine-motif/activation domain of HTLV-I Rex or HIV-1 Rev. The protein that was purified through a Rev-affinity column was found to bind to Rex immunoprecipitated with anti-Rex IgG from an HTLV-I-producing cell line. We analyzed the purified approximately 18-kDa protein biochemically and identified it as prothymosin alpha. The binding activity of prothymosin alpha to Rev or Rex was completely abolished when the epsilon-amino groups of its lysine residues were chemically modified by N-succinimidyl-3-(4-hydroxy-3,5-diodo- phenyl)propionate. The functional relationship between the nuclear protein prothymosin alpha and Rex-Rev is discussed.

The amino terminal domain of HIV-1 Rev is required for discrimination of the RRE from nonspecific RNA.

The ability of HIV-1 Rev to successfully discriminate between specific Rev-responsive elements (RRE) and nonspecific binding sites in the presence of excess nonspecific RNA was examined using filter binding, gel shift, and gel filtration techniques, using purified M4 Rev mutant protein and endoproteinase Lys-C cleaved wild-type Rev. The M4 Rev displayed a slightly reduced binding affinity to the RRE, as well as a tenfold decrease in its ability to discriminate the RRE from non-specific RNA compared to the wild-type Rev. Gel shift and gel filtration chromotography data also showed decreased ability of the mutant to multimerize in the absence or presence of the RRE. The Lys-C cleaved Rev, which lacks the amino-terminal 20 amino acids of the protein, displayed less ability to discriminate the RRE from nonspecific RNA compared to either the wild-type or the M4 mutant Rev and appeared unable to form protein-protein interactions, yet still bound sense and antisense RNA species with high affinity (Kd was in the nanomolar concentration range). A 40 amino acid peptide containing the arginine-rich RRE binding domain of Rev was also observed to interact with both the RRE and antisense RNA fragments with a binding constant of about 1 x 10(-9) M. However, the peptide displayed almost no ability to discriminate between the RRE and a comparably sized antisense RRE. The loss in ability to discriminate correct from incorrect binding sites correlates with overall decreases in the alpha-helical character of the protein and perturbations within the amino terminus. The amino terminus of Rev is likely to maintain the conformational integrity of the arginine rich RRE binding domain which is required for specific RNA binding site discrimination or stabilization of specific Rev-RRE interactions.

Tools for the production and purification of full-length, N- or C-terminal 32P-labeled protein, applied to HIV-1 Gag and Rev.

We have constructed two new vectors for the production of foreign proteins in Escherichia coli. The vectors, pGEX-GTH and pET-HTG, produce protein fused to glutathione S-transferase (GST) at the N- and C-termini, respectively, allowing one-step purification on glutathione-Sepharose. Furthermore, they carry the recognition sequence (RRASV) for the catalytic subunit of cAMP-dependent heart muscle kinase (HMK) at the terminus distal to the GST tag, enabling specific 32P labeling in vitro. By positioning the GST and HMK sequences at opposite ends of the introduced gene, only full-length fusion protein becomes radiolabeled after purification. Avoiding the labeling of shorter fusion protein species, often observed in bacterial expression of foreign genes, is particularly important for a number of different purposes, including protein mobility shift analysis and protein footprinting technology.

Identification of a novel cellular cofactor for the Rev/Rex class of retroviral regulatory proteins.

HIV-1 Rev is the prototype of a class of retroviral regulatory proteins that induce the sequence-specific nuclear export of target RNAs. This function requires the Rev activation domain, which is believed to bind an essential cellular cofactor. We report the identification of a novel human gene product that binds to not only the HIV-1 Rev activation domain in vitro and in vivo but also to functionally equivalent domains in other Rev and Rex proteins. The Rev/Rex activation domain-binding (Rab) protein occupies a binding site on HIV-1 Rev that precisely matches that predicted by genetic analysis. Rab binds the Rev activation domain when Rev is assembled onto its RNA target and can significantly enhance Rev activity when overexpressed. We conclude that Rab is the predicted activation domain-specific cofactor for the Rev/Rex class of RNA export factors.

Expression and purification of the HIV type 1 Rev protein produced in Escherichia coli and its use in the generation of monoclonal antibodies.

We have developed a simple and rapid procedure for the purification of large amounts of Rev protein overexpressed in E. coli. The purification method, which does not require denaturation of the protein, takes advantage of the positively charged nature of Rev and the ability of Rev to interact with nucleic acids. The purified protein was used to develop three novel murine monoclonal antibodies against Rev. Using fusion proteins between glutathione S-transferase (GST) and various fragments of the Rev protein, we mapped the specificity of these antibodies to different regions of the Rev protein. One antibody, 3H6, is directed against the nucleolar localization/RRE-binding domain of Rev between amino acids 38 and 44. Another antibody, 3G4, recognizes an epitope between amino acids 90 and 116 of Rev. A third antibody, 2G2, does not recognize any of the fusion proteins, and may be directed against a conformational epitope. All three antibodies are able to detect Rev on Western blots and to immunoprecipitate Rev under native conditions. However, only 3H6 and 3G4 immunoprecipitate Rev under denaturing conditions and are able to detect Rev expressed in transfected cells by indirect immunofluorescence. These antibodies should prove useful in further studies of Rev function.

Subcellular distribution of human immunodeficiency virus type 1 Rev and colocalization of Rev with RNA splicing factors in a speckled pattern in the nucleoplasm.

The human immunodeficiency virus type 1 (HIV-1) Rev (regulator of virion protein expression) protein exemplifies a new type of posttranscriptional regulation. One main function of Rev is to increase the cytoplasmic expression of unspliced and incompletely spliced retroviral mRNAs from which viral structural proteins are made. In that way, Rev is essential in order to complete the retroviral life cycle. The biology of Rev in the host cell has remained elusive. In this study, a complex distribution of Rev in single cells was found. Rev was found in the cytoplasm, in a perinuclear zone, in the nucleoplasm, and in the nucleoli. In the nucleoplasm, Rev colocalized in a speckled pattern with host cell factors known to assemble on nascent transcripts. Those factors are involved in the processing of heterogeneous RNA to spliced mRNA in the nucleoplasm of all cells. The distribution of Rev was dependent only on Rev and host cell interactions, since neither the Rev target RNA nor other HIV proteins were expressed in the cells. Rev was found in the same subcellular compartments of cells treated for extended periods with cycloheximide, an inhibitor of protein synthesis. This finding implies that Rev shuttles continuously between cytoplasmic and nucleoplasmic compartments. The results suggest a potential role for Rev both in the RNA-splicing process and in the nucleocytoplasmic transport of Rev-dependent HIV mRNA.

Solution oligomerization of the rev protein of HIV-1: implications for function.

rev is an RNA-binding protein of human immunodeficiency virus-1 and is required for the expression of incompletely spliced viral transcripts. Oligomerization of rev is thought to be associated with RNA binding and rev function. Here, we have characterized the oligomerization of rev using equilibrium analytical centrifugation. rev is predominantly monomeric at low concentrations, but reversibly polymerizes to produce large aggregates at higher concentrations. The data fit well to an unlimited isodesmic self-association model in which the association constants for the addition of a monomer to each aggregate are equal [K = 1.08 x 10(6) M-1 at 4 degrees C]. The association constant is essentially independent of monovalent salt concentration from 0.15 to 2 M at pH 6-9. Thermodynamic parameters derived from the temperature dependence of the association constant over the limited range of 0-30 degrees C reveal that the primary contribution to the free energy of oligomerization is a large negative enthalpy. Binding of rev to the rev-responsive element of RNA was characterized under the same conditions as the centrifugation experiments using a nitrocellulose filter assay. rev binds to the RRE at a protein concentration where rev is predominantly monomeric, suggesting that solution multimerization of rev is not required for rev function.

The VP16 transcription activation domain is functional when targeted to a promoter-proximal RNA sequence.

Among eukaryotic transcription trans-activators, the human immunodeficiency virus type 1 (HIV-1) Tat protein is exceptional in that its target site TAR is an RNA rather than a DNA sequence. Here, we confirm that fusion of Tat to the RNA-binding domain of the HIV-1 Rev protein permits the efficient activation of an HIV-1 long terminal repeat (LTR) promoter in which critical TAR sequences have been replaced by RNA sequences derived from the HIV-1 Rev response element (RRE). An RRE target sequence as small as 13 nucleotides is shown to form an effective in vivo target for Rev binding. More important, a fusion protein consisting of Rev attached to the VP16 transcription activation domain was also observed to efficiently activate the HIV-1 LTR from this nascent RNA target. These data demonstrate that trans-activation of transcription by acidic activation domains does not require a stable interaction with the promoter DNA and suggest that VP16, like Tat, can act on steps subsequent to the formation of the HIV-1 LTR preinitiation complex. The finding that the activation domains of VP16 and Tat are functionally interchangeable raises the possibility that these apparently disparate viral trans-activators may nevertheless act via similar mechanisms.

Identification of the Rev transactivation and Rev-responsive elements of feline immunodeficiency virus.

Spliced messages encoded by two distinct strains of feline immunodeficiency virus (FIV) were identified. Two of the cDNA clones represented mRNAs with bicistronic capacity. The first coding exon contained a short open reading frame (orf) of unknown function, designated orf 2. After a translational stop, this exon contained the L region of the env orf. The L region resides 5' to the predicted leader sequence of env. The second coding exon contained the H orf, which began 3' to env and extended into the U3 region of the long terminal repeat. The in-frame splicing of the L and H orfs created the FIV rev gene. Site-directed antibodies to the L orf recognized a 23-kDa protein in infected cells. Immunofluorescence studies localized Rev to the nucleoli of infected cells. The Rev-responsive element (RRE) of FIV was initially identified by computer analysis. Three independent isolates of FIV were searched in their entirety for regions with unusual RNA-folding properties. An unusual RNA-folding region was not found at the Su-TM junction but instead was located at the end of env. Minimal-energy foldings of this region revealed a structure that was highly conserved among the three isolates. Transient expression assays demonstrated that both the Rev and RRE components of FIV were necessary for efficient reporter gene expression. Cells stably transfected with rev-deleted proviruses produced virion-associated reverse transcriptase activity only when FIV Rev was supplied in trans. Thus, FIV is dependent on a fully functional Rev protein and an RRE for productive infection.

Oligomerization and RNA binding domains of the type 1 human immunodeficiency virus Rev protein: a dual function for an arginine-rich binding motif.

The Rev protein of human immunodeficiency virus type 1 is a sequence-specific RNA binding protein that is essential for viral replication. Here we present evidence that Rev is a stable oligomer both in vitro and in vivo. Analysis of Rev mutants indicates that oligomerization is essential for RNA binding and hence Rev function. The oligomerization and RNA binding domains overlap over 47 amino acids. Within this region is a short arginine-rich motif found in a large class of RNA binding proteins. Substitution of multiple residues within the arginine-rich motif abolishes oligomerization, whereas several single-amino-acid substitution mutants oligomerize but do not bind RNA. Thus, Rev's arginine-rich motif participates in two distinct functions: oligomerization and RNA binding.

HIV-1 Rev expressed in recombinant Escherichia coli: purification, polymerization, and conformational properties.

The high-level expression of HIV-1 Rev in Escherichia coli is described. Protein in crude bacterial extracts was dissociated from bound nucleic acid with urea. A simple purification and renaturation protocol, monitored by circular dichroism, is described which results in high yields of pure protein. The purified protein binds with high affinity to the Rev-responsive element mRNA and has nativelike spectroscopic properties. The protein exhibits concentration-dependent self-association as judged by analytical ultracentrifugation and gel filtration measurements. Purified Rev showed reversible heat-induced aggregation over the temperature range 0-30 degrees C. This hydrophobic-driven and nonspecific protein association was inhibited by low concentrations of sulfate ions. Rev solutions at greater than 80 micrograms/mL, incubated at 0-4 degrees C, slowly polymerized to form long hollow fibers of 20-nm diameter. Filament formation occurs at a lower protein concentration and more rapidly in the presence of Rev-responsive mRNA. The nucleic acid containing filaments are about 8 nm in diameter and up to 0.4 micron in length. On the basis of physical properties of the purified protein, we have suggested that in the nucleus of infected cells, Rev binding to the Rev-responsive region of env mRNA may be followed by helical polymerization of the protein which results in coating of the nucleic acid. Coated nucleic acid could be protected from splicing in the nucleus and exported to the cytoplasm.

Specific complex of human immunodeficiency virus type 1 rev and nucleolar B23 proteins: dissociation by the Rev response element.

The human immunodeficiency virus type 1 (HIV) Rev protein is thought to be involved in the export of unspliced or singly spliced viral mRNAs from the nucleus to the cytoplasm. This function is mediated by a sequence-specific interaction with a cis-acting RNA element, the Rev response element (RRE), present in these intron-containing RNAs. To identify possible host proteins involved in Rev function, we fractionated nuclear cell extracts with a Rev affinity column. A single, tightly associated Rev-binding protein was identified; this protein is the mammalian nucleolar protein B23. The interaction between HIV Rev and B23 is very specific, as it was observed in complex cell extracts. The complex is also very stable toward dissociation by high salt concentrations. Despite the stability of the Rev-B23 protein complex, the addition of RRE, but not control RNA, led to the displacement of B23 and the formation of a specific Rev-RRE complex. The mammalian nucleolar protein B23 or its amphibian counterpart No38 is believed to function as a shuttle receptor for the nuclear import of ribosomal proteins. B23 may also serve as a shuttle for the import of HIV Rev from the cytoplasm into the nucleus or nucleolus to allow further rounds of export of RRE-containing viral RNAs.

HIV-1 structural gene expression requires the binding of multiple Rev monomers to the viral RRE: implications for HIV-1 latency.

Expression of the structural proteins of HIV-1 requires the direct interaction of the viral Rev trans-activator with its cis-acting RNA target sequence, the Rev response element or RRE. Here, we demonstrate that this specific RNA-binding event is, as expected, mediated by the conserved arginine-rich motif of Rev. However, we also show that amino acid residues located proximal to this basic domain that are critical for in vivo Rev function are dispensable for sequence-specific binding to the RRE. Instead, these sequences are required for the multimerization of Rev on the viral RRE target sequence. The observation that Rev function requires the sequential binding of multiple Rev molecules to the RRE provides a biochemical explanation for the observed threshold effect for Rev function in vivo and suggests a molecular model for the high incidence of latent infection by HIV-1.

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.

Structural and functional analysis of the human immunodeficiency virus type 2 Rev protein.

The Rev proteins of the human immunodeficiency virus (HIV) are necessary for expression of viral structural gene products. Site-directed mutations were made within the HIV-2 rev gene to identify functional domains. We observed that similar to HIV-1 Rev, the HIV-2 Rev protein was phosphorylated, albeit to a much lesser extent than was HIV-1 Rev. We also found that like HIV-1 Rev, HIV-2 Rev localized to the nucleus, with a marked accumulation in the nucleolus. Mutations within a stretch of basic residues prevented both nuclear and nucleolar localization. Furthermore, mutant Rev proteins able to localize in the nucleus but unable to localize in the nucleolus were nonfunctional.

Purification and characterization of recombinant Rev protein of human immunodeficiency virus type 1.

Recombinant Rev protein of human immunodeficiency virus type 1 has been expressed in Escherichia coli and purified by ion-exchange and gel-filtration chromatography. Specific binding of the purified protein to the Rev-responsive element of the viral RNA is demonstrated. Physical characterization of the purified protein by circular dichroism and intrinsic fluorescence spectroscopy indicate that the protein preparation is suitable for structural analysis. Circular dichroism measurements show that the protein is approximately 40-45% alpha-helix. Tryptophan fluorescence measurements suggest that the single tryptophan residue is located near the surface of the protein. Gel-filtration chromatography of the protein indicates that it has an apparent molecular mass of 33,000 daltons. This suggests that the protein in solution forms a stable tetramer consisting of monomers having molecular mass of 13,000 daltons.