Identification of the membrane-spanning domain of glycoprotein 45 in bovine immunodeficiency virus.

The membrane-spanning domain (MSD) of the transmembrane subunit (TM) anchors the envelope glycoprotein (Env) on the lipid bilayer of the host cell membrane and virions. Its functions include membrane fusion efficiency and intracellular trafficking of the lentivirus envelope protein. Our study aimed to determine the MSD of bovine immunodeficiency virus (BIV) glycoprotein 45 (gp45) and reveal structural characteristics of the BIV Env protein. We have predicted the region of the BIV MSD and obtained the sequence using bioinformatics software. Various kinds of assays, including analogy analysis, fluorescence microscopy, and dye-transfer-based assays, were carried out to validate the prediction. The results, for the first time, show that the BIV MSD is located at the D170 to M191 amino acids of gp45, and the identified MSD divides gp45 into the extracellular domain (ED), MSD and cytoplasmic domain (CT). We further found that the BIV MSD had a similar structure and function as the HIV MSD using amino acid sequence alignment and fluorescence microscopy. Additionally, the dye-transfer-based assay demonstrates that deletion of the BIV MSD efficiently decreases cell-cell fusion. Based on the identification of the MSD, a "snorkeling" model, in which the flanking charged amino acid residues are buried in the lipid bilayer while their side chains interact with polar head groups, was proposed for the BIV MSD. Ultimately, we further improved the primary structure of the BIV envelope glycoprotein.

Global pairwise RNA interaction landscapes reveal core features of protein recognition.

RNA-protein interactions permeate biology. Transcription, translation, and splicing all hinge on the recognition of structured RNA elements by RNA-binding proteins. Models of RNA-protein interactions are generally limited to short linear motifs and structures because of the vast sequence sampling required to access longer elements. Here, we develop an integrated approach that calculates global pairwise interaction scores from in vitro selection and high-throughput sequencing. We examine four RNA-binding proteins of phage, viral, and human origin. Our approach reveals regulatory motifs, discriminates between regulated and non-regulated RNAs within their native genomic context, and correctly predicts the consequence of mutational events on binding activity. We design binding elements that improve binding activity in cells and infer mutational pathways that reveal permissive versus disruptive evolutionary trajectories between regulated motifs. These coupling landscapes are broadly applicable for the discovery and characterization of protein-RNA recognition at single nucleotide resolution.

Evolution of a designed protein assembly encapsulating its own RNA genome.

The challenges of evolution in a complex biochemical environment, coupling genotype to phenotype and protecting the genetic material, are solved elegantly in biological systems by the encapsulation of nucleic acids. In the simplest examples, viruses use capsids to surround their genomes. Although these naturally occurring systems have been modified to change their tropism and to display proteins or peptides, billions of years of evolution have favoured efficiency at the expense of modularity, making viral capsids difficult to engineer. Synthetic systems composed of non-viral proteins could provide a 'blank slate' to evolve desired properties for drug delivery and other biomedical applications, while avoiding the safety risks and engineering challenges associated with viruses. Here we create synthetic nucleocapsids, which are computationally designed icosahedral protein assemblies with positively charged inner surfaces that can package their own full-length mRNA genomes. We explore the ability of these nucleocapsids to evolve virus-like properties by generating diversified populations using Escherichia coli as an expression host. Several generations of evolution resulted in markedly improved genome packaging (more than 133-fold), stability in blood (from less than 3.7% to 71% of packaged RNA protected after 6 hours of treatment), and in vivo circulation time (from less than 5 minutes to approximately 4.5 hours). The resulting synthetic nucleocapsids package one full-length RNA genome for every 11 icosahedral assemblies, similar to the best recombinant adeno-associated virus vectors. Our results show that there are simple evolutionary paths through which protein assemblies can acquire virus-like genome packaging and protection. Considerable effort has been directed at 'top-down' modification of viruses to be safe and effective for drug delivery and vaccine applications; the ability to design synthetic nanomaterials computationally and to optimize them through evolution now enables a complementary 'bottom-up' approach with considerable advantages in programmability and control.

Thermodynamics and solvation dynamics of BIV TAR RNA-Tat peptide interaction.

The interaction of the trans-activation responsive (TAR) region of bovine immunodeficiency virus (BIV) RNA with the Tat peptide is known to play important role in viral replication. Despite being thoroughly studied through a structural point of view, the nature of binding between BIV TAR RNA and the BIV Tat peptide requires information related to its thermodynamics and the nature of hydration around the TAR-Tat complex. In this context, we carried out the thermodynamic study of binding of the Tat peptide to the BIV TAR RNA hairpin through different calorimetric and spectroscopic measurements. Fluorescence titration of 2-aminopurine tagged BIV TAR RNA with the Tat peptide gives their binding affinity. The isothermal titration calorimetric experiment reveals the enthalpy of binding between BIV TAR RNA and the Tat peptide to be largely exothermic with the value of -11.7 (SEM 0.2) kcal mol(-1). Solvation dynamics measurements of BIV TAR RNA having 2-AP located at the bulge region have been carried out in the absence and presence of the BIV Tat peptide using the time correlated single photon counting technique. The solvent cage around the Tat binding site of RNA appears to be more rigid in the presence of the Tat peptide as compared to the free RNA. The displacement of solvent and ions on RNA due to peptide binding influences the entropic contributions to the total binding energy.

Tethering of proteins to RNAs using the bovine immunodeficiency virus-Tat peptide and BIV-TAR RNA.

To study the functions of RNA-binding proteins independent of their RNA-binding activity, tethering methods have been developed, based on the use of the RNA-binding domain of a well-characterized RNA-binding protein and its target RNA. Two bacteriophage proteins have mainly been used as tethers: the MS2 coat protein and the lambda N protein. Here we report an alternative system using the Tat (trans-activator) peptide from the bovine immunodeficiency virus (BIV), which binds to BIV-TAR (trans-activation response) RNA. We demonstrate the usefulness of this system by applying it to the analysis of the TNRC6B protein, a component of the microRNA-induced silencing complex.

Substrate variations that affect the nucleic acid clamp activity of reverse transcriptases.

We have recently shown that reverse transcriptases (RTs) perform template switches when there is a very short (two-nucleotide) complementarity between the 3' ends of the primer (donor) strand and the DNA or RNA template acceptor strands [Oz-Gleenberg et al. (2011) Nucleic Acids Res 39, 1042-1053]. These dinucleotide pairs are stabilized by RTs that are capable of 'clamping' together the otherwise unstable duplexes. This RT-driven stabilization of the micro-homology sequence promotes efficient DNA synthesis. In the present study, we have examined several factors associated with the sequence and structure of the DNA substrate that are critical for the clamp activity of RTs from human immunodeficiency virus type 1 (HIV-1), murine leukemia virus (MLV), bovine immunodeficiency virus (BIV) and the long terminal repeat retrotransposon Tf1. The parameters studied were the minimal complementarity length between the primer and functional template termini that sustains stable clamps, the effects of gaps between the two template strands on the clamp activity of the tested RTs, the effects of template end phosphorylations on the RT-associated clamp activities, and clamp activity with a long 'hairpin' double-stranded primer comprising both the primer and the complementary non-functional template strands. The results show that the substrate conditions for clamp activity of HIV-1 and MLV RTs are more stringent, while Tf1 and BIV RTs show clamp activity under less rigorous substrate conditions. These differences shed light on the dissimilarities in catalytic activities of RTs, and suggest that clamp activity may be a potential new target for anti-retroviral drugs.

[Polypurine/polypyrimidine sequences with potential of forming triplexes in the proviral DNA of bovine retroviruses].

Perfect interstranded triplexes that can potentially arise in the proviral DNA of wide-spread bovine retroviruses like as bovine leukemia virus (BLV) and bovine immunodeficiency virus (BIV) have been determined. In the BLV and BIV genomes 2 and 5 fragments respectively were found to form triple helixes under acidic conditions. One of those fragments that is localized on the BLV gag gene can exist as cruciform structure too. Experimentally the existence of triplexes is confirmed by atomic force microscopic visualization of supercoiled pGEMEX DNA for which genome 6 fragments are found with mirror symmetry that is necessary for intramolecular triplex formation. The diagrams of triplexes (one of the elements of signaling genome function) localization on the genome of bovine retroviruses are obtained.

The bovine immunodeficiency virus rev protein: identification of a novel lentiviral bipartite nuclear localization signal harboring an atypical spacer sequence.

The bovine immunodeficiency virus (BIV) Rev protein (186 amino acids [aa] in length) is involved in the nuclear exportation of partially spliced and unspliced viral RNAs. Previous studies have shown that BIV Rev localizes in the nucleus and nucleolus of infected cells. Here we report the characterization of the nuclear/nucleolar localization signals (NLS/NoLS) of this protein. Through transfection of a series of deletion mutants of BIV Rev fused to enhanced green fluorescent protein and fluorescence microscopy analyses, we were able to map the NLS region between aa 71 and 110 of the protein. Remarkably, by conducting alanine substitution of basic residues within the aa 71 to 110 sequence, we demonstrated that the BIV Rev NLS is bipartite, maps to aa 71 to 74 and 95 to 101, and is predominantly composed of arginine residues. This is the first report of a bipartite Rev (or Rev-like) NLS in a lentivirus/retrovirus. Moreover, this NLS is atypical, as the length of the sequence between the motifs composing the bipartite NLS, e.g., the spacer sequence, is 20 aa. Further mutagenesis experiments also identified the NoLS region of BIV Rev. It localizes mainly within the NLS spacer sequence. In addition, the BIV Rev NoLS sequence differs from the consensus sequence reported for other viral and cellular nucleolar proteins. In summary, we conclude that the nucleolar and nuclear localizations of BIV Rev are mediated via novel NLS and NoLS motifs.

Simultaneous recognition of HIV-1 TAR RNA bulge and loop sequences by cyclic peptide mimics of Tat protein.

The interaction of the HIV-1 transactivator protein Tat with its transactivation response (TAR) RNA is an essential step in viral replication and therefore an attractive target for developing antivirals with new mechanisms of action. Numerous compounds that bind to the 3-nt bulge responsible for binding Tat have been identified in the past, but none of these molecules had sufficient potency to warrant pharmaceutical development. We have discovered conformationally-constrained cyclic peptide mimetics of Tat that are specific nM inhibitors of the Tat-TAR interaction by using a structure-based approach. The lead peptides are nearly as active as the antiviral drug nevirapine against a variety of clinical isolates in human lymphocytes. The NMR structure of a peptide-RNA complex reveals that these molecules interfere with the recruitment to TAR of both Tat and the essential cellular cofactor transcription elongation factor-b (P-TEFb) by binding simultaneously at the RNA bulge and apical loop, forming an unusually deep pocket. This structure illustrates additional principles in RNA recognition: RNA-binding molecules can achieve specificity by interacting simultaneously with multiple secondary structure elements and by inducing the formation of deep binding pockets in their targets. It also provides insight into the P-TEFb binding site and a rational basis for optimizing the promising antiviral activity observed for these cyclic peptides.

RNA detection using peptide-inserted Renilla luciferase.

A novel complementation system with short peptide-inserted-Renilla luciferase (PI-Rluc) and split-RNA probes was constructed for noninvasive RNA detection. The RNA binding peptides HIV-1 Rev and BIV Tat were used as inserted peptides. They display induced fit conformational changes upon binding to specific RNAs and trigger complementation or discomplementation of Rluc. Split-RNA probes were designed to reform the peptide binding site upon hybridization with arbitrarily selected target RNA. This set of recombinant protein and split-RNA probes enabled a high degree of sensitivity in RNA detection. In this study, we show that the Rluc system is comparable to Fluc, but that its detection limit for arbitrarily selected RNA (at least 100 pM) exceeds that of Fluc by approximately two orders of magnitude.

A comparative binding study of modified bovine immunodeficiency virus TAR RNA against its TAT peptide.

Besides generating novel binding peptides or small molecules to their RNA target, successful design of chemically modified RNA constructs capable of tighter binding with their binding peptides is also of significant importance. Herein, the synthesis and binding studies of a series of both wt and mutant bovine immunodeficiency virus (BIV) TAR RNA constructs against its Tat peptide are reported. Understanding the requirements that enable RNA construct binding properties, especially at the hairpin loop or internal bulge, would afford potential therapeutic approaches to control the BIV life cycle.

Structural mimicry of retroviral tat proteins by constrained beta-hairpin peptidomimetics: ligands with high affinity and selectivity for viral TAR RNA regulatory elements.

An approach is described to the design of beta-hairpin peptidomimetic ligands for bovine immunodeficiency virus (BIV) Tat protein, which inhibit binding to its transactivator response element (TAR) RNA. A library of peptidomimetics was derived by grafting onto a hairpin-inducing d-Pro-l-Pro template sequences related to the RNA recognition element in Tat. One hairpin mimetic was identified that binds tightly (K(d) approximately 150 nM) to BIV TAR, and another that binds also to HIV-1 TAR RNA (K(d) approximately 1-2 microM). (In the same assay, the wild-type BIV Tat(65-81) peptide binds to BIV TAR with K(d) approximately 50 nM.) The high-affinity BIV-Tat mimetic was shown to adopt a stable beta-hairpin conformation in free solution by NMR methods. Amino acid substitutions in this mimetic were shown to impact on the hairpin structure and to disrupt binding to the RNA. This family of conformationally constrained peptidomimetics affords insights into the structural requirements for binding to TAR RNA and provides a basis for the design of new ligands with increased inhibitory activity and specificity to both BIV and HIV TAR RNAs.

Important role for the CA-NC spacer region in the assembly of bovine immunodeficiency virus Gag protein.

Lentiviral Gag proteins contain a short spacer sequence that separates the capsid (CA) from the downstream nucleocapsid (NC) domain. This short spacer has been shown to play an important role in the assembly of human immunodeficiency virus type 1 (HIV-1). We have now extended this finding to the CA-NC spacer motif within the Gag protein of bovine immunodeficiency virus (BIV). Mutation of this latter spacer sequence led to dramatic reductions in virus production, which was mainly attributed to the severely disrupted association of the mutated Gag with the plasma membrane, as shown by the results of membrane flotation assays and confocal microscopy. Detailed mutagenesis analysis of the BIV CA-NC spacer region for virus assembly determinants led to the identification of two key residues, L368 and M372, which are separated by three amino acids, 369-VAA-371. Incidentally, the same two residues are present within the HIV-1 CA-NC spacer region at positions 364 and 368 and have also been shown to be crucial for HIV-1 assembly. Regardless of this conservation between these two viruses, the BIV CA-NC spacer could not be replaced by its HIV-1 counterpart without decreasing virus production, as opposed to its successful replacement by the CA-NC spacer sequences from the nonprimate lentiviruses such as feline immunodeficiency virus (FIV), equine infectious anemia virus and visna virus, with the sequence from FIV showing the highest effectiveness in this regard. Taken together, these data suggest a pivotal role for the CA-NC spacer region in the assembly of BIV Gag; however, the mechanism involved therein may differ from that for the HIV-1 CA-NC spacer.

Design of a cyclic peptide that targets a viral RNA.

The Tat protein controls transcription in lentiviruses such as HIV. A cyclic peptide analog of the RNA binding domain of the bovine immunodeficiency virus (BIV) Tat protein is shown to bind specifically to its target RNA stem loop. NMR data indicate a similar mode of binding of linear and cyclic peptides.

Unique epitope of bovine immunodeficiency virus gag protein spans the cleavage site between p16(MA) and p2L.

Bovine immunodeficiency virus (BIV) and Jembrana disease virus (JDV) are closely related bovine lentiviruses that are difficult to distinguish by presently available diagnostic methods. Recently, in our laboratory, a monoclonal antibody (MAb; MAb 10H1) against the BIV Gag protein identified a differential epitope, located at the 6.4-kDa N terminus of a 29-kDa Gag capsid protein, which was absent in JDV. To define the essential amino acids of the epitope, a series of primers within the 163 bp of DNA corresponding to the 6.4-kDa protein were designed. The full-length 163-bp DNA fragment and the smaller DNA fragments with deletions were amplified by PCR and then cloned into pQE32 vectors for protein expression studies. The expressed proteins were analyzed with MAb 10H1 by Western blotting. The differential epitope has been narrowed to a 26-amino-acid region (R121 to R146), which includes 6 residues of p16(MA) (where MA represents the matrix protein) and 20 residues of p2L. A synthetic peptide corresponding to the putative 26-amino-acid epitope blocked MAb 10H1 binding to the expressed peptide. These experiments revealed that the epitope spans the cleavage site between p16(MA) and p2L and presumably will be valuable in distinguishing the two viruses.

Flexibility of BIV TAR-Tat: models of peptide binding.

A new approach in determining local residue flexibility from base-amino acid contact frequencies is applied to the twelve million lattice chains modeling BIV Tat peptide binding to TAR RNA fragment. Many of the resulting key features in flexibility correspond to RMSD calculations derived from a set of five NMR derived structures (X. Ye, R. A. Kumar, and D. J. Patel, Protein Data Bank: Database of three-dimensional structures determined from NMR (1996)) and binding studies of mutants (L. Chen and A. D. Frankel, Proc. Natl. Acad. Sci. USA 92, 5077-5081 (1995)). The lattice and RMSD calculations facilitate the identification of peptide hinge regions that can best utilize the introduction of Gly or other flexible residues. This approach for identifying potential sites amenable to substitution of more flexible residues to enhance peptide binding to RNA targets could be a useful design tool.

Molecular dynamics and binding specificity analysis of the bovine immunodeficiency virus BIV Tat-TAR complex.

We have performed molecular dynamics (MD) simulations, with particle-mesh Ewald, explicit waters, and counterions, and binding specificity analyses using combined molecular mechanics and continuum solvent (MM-PBSA) on the bovine immunodeficiency virus (BIV) Tat peptide-TAR RNA complex. The solution structure for the complex was solved independently by Patel and co-workers and Puglisi and co-workers. We investigated the differences in both structures and trajectories, particularly in the formation of the U-A-U base triple, the dynamic flexibility of the Tat peptide, and the interactions at the binding interface. We observed a decrease in RMSD in comparing the final average RNA structures and initial RNA structures of both trajectories, which suggests the convergence of the RNA structures to a MD equilibrated RNA structure. We also calculated the relative binding of different Tat peptide mutants to TAR RNA and found qualitative agreement with experimental studies.

Structural model of the HIV-1 Tat(46-58)-TAR complex.

The trans-activator protein (Tat) of human immunodeficiency virus type 1 (HIV-1) binds to an uridine-rich bulge of an RNA target (TAR; trans-activation responsive element) predominantly via its basic sequence domain. The structure of the Tat(46-58)-TAR complex has been determined by a novel modeling approach relying on structural information about one crucial arginine residue and crosslink data. The strategy described here solely uses this experimental data without additional "modeling" assumptions about the structure of the complex in order to avoid human bias. Model building was performed in a fashion similar to structure calculations from nuclear magnetic resonance (NMR)-spectroscopic data using restrained molecular dynamics. The resulting set of structures of Tat(46-58) in its complex with TAR reveals that all models have converged to a common fold, showing a backbone root mean square deviation (RMSD) of 1.36A. Analysis of the calculated structures suggests that HIV-I Tat forms a hairpin loop in its complex with TAR that shares striking similarity to the hairpin formed by the structure of the bovine immunodeficiency virus Tat protein after TAR binding as determined by NMR studies. The outlined approach is not limited to the Tat-TAR complex modeling, but is also applicable to all molecular complexes with sufficient biochemical and biophysical data available.

Sequence data analysis reveals a relationship between LSR2, the recombinant fusion protein mimicing M. Leprae and VIF of bovine immunodeficiency virus (BIV).

In the course of computer simulation study looking for active sites for the interaction between MHC II and T7--a 12 residue long peptide of LSR2--a recombinant fusion protein mimicing the native bacillus M.Leprae--an interesting relationship between the antigenicity of LSR2 and VIF of BIF has come to light. Computer analysis study has revealed this stretch of residue from 36 to 48 of LSR2 is highly antigenic. The experimental observation seems to confirm the role of this 12 residue peptide in antibody response. In an effort to determine whether a significant sequence level relationship exists between this and any other known protein, the sequence homology of both protein and nucleic acid was studied. It is found that this 12 residue long peptide (T7) of LSR2 is homologous with Viral Infectivity Factor (VIF) of the Bovine Immunodeficiency Virus (BIV). Homology with translated nucleic acid sequence also indicate the same fact. The VIF gene which codes for this protein is known to be essential for ability of cell-free virus preparation to infect cells. These results lead to the question--whether this 12 residue long peptide which is common to both proteins play a role in their infectivity. Whether mutations in the peptide or elimination of this peptide from the protein and studying the effect of this on the diseases themselves may help in controlling them is another important question relevant to medical researchers.

A docking and modelling strategy for peptide-RNA complexes: applications to BIV Tat-TAR and HIV Rev-RBE.

BACKGROUND: In spite of the great interest in the interaction between RNAs and proteins, no general protocol for modelling these complexes is presently available. This methodological vacuum is particularly acute because the structure of few such complexes is known. RESULTS: A general strategy for docking and modelling RNA-protein complexes has been developed. The docking procedure involves minimizing electrostatic and van der Waals' interaction energies of conformationally rigid structures during docking. After docking, libraries of amino acid sidechain conformations are searched to obtain the best interactions between the peptide and the RNA. Using this method, we have reproduced the structure of a bovine immunodeficiency virus (BIV) Tat peptide bound to BIV TAR RNA and have developed a model for the structure of the arginine-rich HIV-1 Rev peptide (Rev34-50) interacting with the Rev-binding element (RBE). CONCLUSIONS: The resulting model of the Rev34-50-RBE complex predicts that although no single arginine sidechain is responsible for complex formation, residues Arg2, Arg5 and Arg11 are more important for binding than the other arginine residues in the peptide. One model is supported by binding measurements performed on wild-type and mutant RBE molecules with the peptide.