Oligomeric viral proteins: small in size, large in presence.

Viruses are obligate parasites that rely heavily on host cellular processes for replication. The small number of proteins typically encoded by a virus is faced with selection pressures that lead to the evolution of distinctive structural properties, allowing each protein to maintain its function under constraints such as small genome size, high mutation rate, and rapidly changing fitness conditions. One common strategy for this evolution is to utilize small building blocks to generate protein oligomers that assemble in multiple ways, thereby diversifying protein function and regulation. In this review, we discuss specific cases that illustrate how oligomerization is used to generate a single defined functional state, to modulate activity via different oligomeric states, or to generate multiple functional forms via different oligomeric states.

Thermodynamics of Rev-RNA interactions in HIV-1 Rev-RRE assembly.

The HIV-1 protein Rev facilitates the nuclear export of intron-containing viral mRNAs by recognizing a structured RNA site, the Rev-response-element (RRE), contained in an intron. Rev assembles as a homo-oligomer on the RRE using its α-helical arginine-rich-motif (ARM) for RNA recognition. One unique feature of this assembly is the repeated use of the ARM from individual Rev subunits to contact distinct parts of the RRE in different binding modes. How the individual interactions differ and how they contribute toward forming a functional complex is poorly understood. Here we examine the thermodynamics of Rev-ARM peptide binding to two sites, RRE stem IIB, the high-affinity site that nucleates Rev assembly, and stem IA, a potential intermediate site during assembly, using NMR spectroscopy and isothermal titration calorimetry (ITC). NMR data indicate that the Rev-IIB complex forms a stable interface, whereas the Rev-IA interface is highly dynamic. ITC studies show that both interactions are enthalpy-driven, with binding to IIB being 20-30 fold tighter than to IA. Salt-dependent decreases in affinity were similar at both sites and predominantly enthalpic in nature, reflecting the roles of electrostatic interactions with arginines. However, the two interactions display strikingly different partitioning between enthalpy and entropy components, correlating well with the NMR observations. Our results illustrate how the variation in binding modes to different RRE target sites may influence the stability or order of Rev-RRE assembly and disassembly, and consequently its function.

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.

The HIV-1 Rev response element: an RNA scaffold that directs the cooperative assembly of a homo-oligomeric ribonucleoprotein complex.

The HIV-1 Rev response element (RRE) is a ~350 nucleotide, highly structured, cis-acting RNA element essential for viral replication. It is located in the env coding region of the viral genome and is extremely well conserved across different HIV-1 isolates. It is present on all partially spliced and unspliced viral mRNA transcripts, and serves as an RNA framework onto which multiple molecules of the viral protein Rev assemble. The Rev-RRE oligomeric complex mediates the export of these messages from the nucleus to the cytoplasm, where they are translated to produce essential viral proteins and/or packaged as genomes for new virions.

Functional and structural segregation of overlapping helices in HIV-1.

Overlapping coding regions balance selective forces between multiple genes. One possible division of nucleotide sequence is that the predominant selective force on a particular nucleotide can be attributed to just one gene. While this arrangement has been observed in regions in which one gene is structured and the other is disordered, we sought to explore how overlapping genes balance constraints when both protein products are structured over the same sequence. We use a combination of sequence analysis, functional assays, and selection experiments to examine an overlapped region in HIV-1 that encodes helical regions in both Env and Rev. We find that functional segregation occurs even in this overlap, with each protein spacing its functional residues in a manner that allows a mutable non-binding face of one helix to encode important functional residues on a charged face in the other helix. Additionally, our experiments reveal novel and critical functional residues in Env and have implications for the therapeutic targeting of HIV-1.

Highly Mutable Linker Regions Regulate HIV-1 Rev Function and Stability.

HIV-1 Rev is an essential viral regulatory protein that facilitates the nuclear export of intron-containing viral mRNAs. It is organized into structured, functionally well-characterized motifs joined by less understood linker regions. Our recent competitive deep mutational scanning study confirmed many known constraints in Rev's established motifs, but also identified positions of mutational plasticity, most notably in surrounding linker regions. Here, we probe the mutational limits of these linkers by testing the activities of multiple truncation and mass substitution mutations. We find that these regions possess previously unknown structural, functional or regulatory roles, not apparent from systematic point mutational approaches. Specifically, the N- and C-termini of Rev contribute to protein stability; mutations in a turn that connects the two main helices of Rev have different effects in different contexts; and a linker region which connects the second helix of Rev to its nuclear export sequence has structural requirements for function. Thus, Rev function extends beyond its characterized motifs, and is tuned by determinants within seemingly plastic portions of its sequence. Additionally, Rev's ability to tolerate many of these massive truncations and substitutions illustrates the overall mutational and functional robustness inherent in this viral protein.

The HIV-1 Tat protein recruits a ubiquitin ligase to reorganize the 7SK snRNP for transcriptional activation.

The HIV-1 Tat protein hijacks P-TEFb kinase to activate paused RNA polymerase II (RNAP II) at the viral promoter. Tat binds additional host factors, but it is unclear how they regulate RNAP II elongation. Here, we identify the cytoplasmic ubiquitin ligase UBE2O as critical for Tat transcriptional activity. Tat hijacks UBE2O to ubiquitinate the P-TEFb kinase inhibitor HEXIM1 of the 7SK snRNP, a fraction of which also resides in the cytoplasm bound to P-TEFb. HEXIM1 ubiquitination sequesters it in the cytoplasm and releases P-TEFb from the inhibitory 7SK complex. Free P-TEFb then becomes enriched in chromatin, a process that is also stimulated by treating cells with a CDK9 inhibitor. Finally, we demonstrate that UBE2O is critical for P-TEFb recruitment to the HIV-1 promoter. Together, the data support a unique model of elongation control where non-degradative ubiquitination of nuclear and cytoplasmic 7SK snRNP pools increases P-TEFb levels for transcriptional activation.

Discovery of a Branched Peptide That Recognizes the Rev Response Element (RRE) RNA and Blocks HIV-1 Replication.

We synthesized and screened a unique 46 656-member library composed of unnatural amino acids that revealed several hits against RRE IIB RNA. Among the hit peptides identified, peptide 4A5 was found to be selective against competitor RNAs and inhibited HIV-1 Rev-RRE RNA interaction in cell culture in a p24 ELISA assay. Biophysical characterization in a ribonuclease protection assay suggested that 4A5 bound to the stem-loop region in RRE IIB while SHAPE MaP probing with 234 nt RRE RNA indicated additional interaction with secondary Rev binding sites. Taken together, our investigation suggests that HIV replication is inhibited by 4A5 blocking binding of Rev and subsequent multimerization.

RNA-directed remodeling of the HIV-1 protein Rev orchestrates assembly of the Rev-Rev response element complex.

The HIV-1 protein Rev controls a critical step in viral replication by mediating the nuclear export of unspliced and singly-spliced viral mRNAs. Multiple Rev subunits assemble on the Rev Response Element (RRE), a structured region present in these RNAs, and direct their export through the Crm1 pathway. Rev-RRE assembly occurs via several Rev oligomerization and RNA-binding steps, but how these steps are coordinated to form an export-competent complex is unclear. Here, we report the first crystal structure of a Rev dimer-RRE complex, revealing a dramatic rearrangement of the Rev-dimer upon RRE binding through re-packing of its hydrophobic protein-protein interface. Rev-RNA recognition relies on sequence-specific contacts at the well-characterized IIB site and local RNA architecture at the second site. The structure supports a model in which the RRE utilizes the inherent plasticity of Rev subunit interfaces to guide the formation of a functional complex.

Thermodynamic dissection of the Ezrin FERM/CERMAD interface.

ERM (Ezrin-Radixin-Moesin) proteins are key cross-linkers of the plasma membrane and the actin cytoskeleton. They are regulated by the intramolecular association of the N-terminal FERM (band-four point one, Ezrin, Radixin, Moesin) and C-terminal CERMAD (ERM association domain) domains (N/C interaction), which masks the binding surfaces of the domains for other molecules. The N/C interface is characterized by the highly distributed binding of CERMAD through a beta-strand and four alpha-helices to a globular FERM. Though it is a target for multiple regulatory signals, little is known about the dynamics/thermodynamics governing this interface. Recent implications of Ezrin in cancer metastasis have increased the necessity to understand this regulatory switch. In this study, we report residue-specific stabilities of Ezrin CERMAD at the Ezrin N/C interface obtained using hydrogen-deuterium exchange NMR. These stabilities vary across secondary structural elements and identify F583 and L586 as key anchor residues for the most stable element, alphaD. Macroscopic N/C binding energetics, obtained using isothermal titration calorimetry (ITC) reveals a high affinity (Kd =176 nM) enthalpy-driven binding (DeltaH = -26 kcal/mol, TDeltaS = -17 kcal/mol) at 25 degrees C at pH 7 in MES and phosphate buffers. A 10-fold increase in affinity was observed for measurements in acetate buffer, suggesting that an acetate-like molecule might promote the repressed form of the complex, possibly through interaction with the F2 subdomain of FERM, which resembles the acyl-CoA binding protein. In summary, our results have illustrated the dynamic nature of this regulatory interface and provide a foundation for investigating the role of regulatory signals on the stability of this interface.