Alpha helix-RNA major groove recognition in an HIV-1 rev peptide-RRE RNA complex.

The solution structure of a human immunodeficiency virus type-1 (HIV-1) Rev peptide bound to stem-loop IIB of the Rev response element (RRE) RNA was solved by nuclear magnetic resonance spectroscopy. The Rev peptide has an alpha-helical conformation and binds in the major groove of the RNA near a purine-rich internal loop. Several arginine side chains make base-specific contacts, and an asparagine residue contacts a G.A base pair. The phosphate backbone adjacent to a G.G base pair adopts an unusual structure that allows the peptide to access a widened major groove. The structure formed by the two purine-purine base pairs of the RRE creates a distinctive binding pocket that the peptide can use for specific recognition.

Utilization of site-directed spin labeling and high-resolution heteronuclear nuclear magnetic resonance for global fold determination of large proteins with limited nuclear overhauser effect data.

To test whether distances derived from paramagnetic broadening of (15)N heteronuclear single quantum coherence (HSQC) resonances could be used to determine the global fold of a large, perdeuterated protein, we used site-directed spin-labeling of 5 amino acids on the surface of (15)N-labeled eukaryotic translation initiation factor 4E (eIF4E). eIF4E is a 25 kDa translation initiation protein, whose solution structure was previously solved in a 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate hydrate (CHAPS) micelle of total molecular mass approximately 45-50 kDa. Distance-dependent line broadening consistent with the three-dimensional structure of eIF4E was observed for all spin-label substitutions. The paramagnetic broadening effects (PBEs) were converted into distances for modeling by a simple method comparing peak heights in (15)N-HSQC spectra before and after reduction of the nitroxide spin label with ascorbic acid. The PBEs, in combination with HN-HN nuclear Overhauser effects (NOEs) and chemical shift index (CSI) angle restraints, correctly determined the global fold of eIF4E with a backbone precision of 2.3 A (1.7 A for secondary structure elements). The global fold was not correctly determined with the HN-HN NOEs and CSI angles alone. The combination of PBEs with simulated restraints from another nuclear magnetic resonance (NMR) method for global fold determination of large proteins (methyl-protonated, highly deuterated samples) improved the quality of calculated structures. In addition, the combination of the two methods simulated from a crystal structure of an all alpha-helical protein (40 kDa farnesyl diphoshphate synthase) correctly determined the global fold where neither method individually was successful. These results show the potential feasibility of obtaining medium-resolution structures for proteins in the 40-100 kDa range via NMR.

Binding of an HIV Rev peptide to Rev responsive element RNA induces formation of purine-purine base pairs.

The Rev responsive element (RRE) is an RNA secondary structural element within the env gene of HIV and is the binding site for the viral Rev protein. Formation of the Rev-RRE complex is involved in regulation of splicing and transport of mRNA from the nucleus. To understand the structural basis for the specific recognition of RRE by Rev, we have studied a model system for this interaction using NMR. We have obtained a specific 1:1 complex between an RNA derived from stem IIB of RRE, which contains the highest affinity Rev binding site, and a modified Rev34-50 peptide, which binds the RRE as an alpha-helix [Tan, R., et al. (1993) Cell 73, 1031-1040]. Binding of the peptide was accompanied by a conformational change in the RNA, which resulted in the formation of additional base pairs not present in the free RNA. Two of these induced base pairs are purine-purine pairs within the internal loop of RRE, which had been previously proposed on the basis of biochemical experiments [Bartel, D.P., et al. (1991) Cell 67, 529-536]. The formation of non-Watson-Crick base pairs, interactions in the major groove, and protein-induced conformational changes may prove to be common characteristics of RNA recognition of proteins.

Interaction of HIV Rev peptides with the Rev response element RNA.

As a model system for understanding RNA-protein interactions, we are studying the structure of peptides derived from HIV Rev in complex with an RNA derived from the Rev Response Element (RRE) using NMR spectroscopy. Formation of the Rev peptide-RRE complex is accompanied by formation of two purine-purine base pairs in the RRE. These base pairs create an unusual geometry that widens the major groove of the RRE RNA. The Rev peptide is predominantly in an alpha-helical conformation in the complex. The specific recognition of the RRE by Rev involves widening of the major groove to accommodate the Rev alpha-helix.

Assignment and modeling of the Rev Response Element RNA bound to a Rev peptide using 13C-heteronuclear NMR.

The Rev Response Element (RRE) RNA-Rev protein interaction is important for regulation of gene expression in the human immunodeficiency virus. A model system for this interaction, which includes stem IIB of the RRE RNA and an arginine-rich peptide from the RNA-binding domain of Rev, was studied using multidimensional heteronuclear NMR. Assignment of the RNA when bound to the peptide was obtained from NMR experiments utilizing uniformly and specifically 13C-labeled RNA. Isotopic filtering experiments on the specifically labeled RNA enable unambiguous assignment of unusual nonsequential NOE patterns present in the internal loop of the RRE. A three-dimensional model of the RNA in the complex was obtained using restrained molecular dynamics calculations. The internal loop contains two purine-purine base pairs, which are stacked to form one continuous helix flanked by two A-form regions. The formation of a G-G base pair in the internal loop requires an unusual structure of the phosphate backbone. This structural feature is consistent with mutational data as being important for the binding of Rev to the RRE. The G-G base pair may play an important role in opening the normally narrow major groove of A-form RNA to permit binding of the Rev basic domain.

The eIF1A solution structure reveals a large RNA-binding surface important for scanning function.

The translation initiation factor eIF1A is necessary for directing the 43S preinitiation complex from the 5' end of the mRNA to the initiation codon in a process termed scanning. We have determined the solution structure of human eIF1A, which reveals an oligonucleotide-binding (OB) fold and an additional domain. NMR titration experiments showed that eIF1A binds single-stranded RNA oligonucleotides in a site-specific, but non-sequence-specific manner, hinting at an mRNA interaction rather than specific rRNA or tRNA binding. The RNA binding surface extends over a large area covering the canonical OB fold binding site as well as a groove leading to the second domain. Site-directed mutations at multiple positions along the RNA-binding surface were defective in the ability to properly assemble preinitiation complexes at the AUG codon in vitro.

Recent advances in RNA structure determination by NMR.

Despite recent advances in the solution of NMR structures of RNA and RNA-ligand complexes, the rate limiting step remains the gathering of a large number of NOE and torsion restraints. Additional sources of information for structure determination of larger RNA molecules have recently become available, and it is possible to supplement NOE and J-coupling data with the measurement of dipolar couplings and cross-correlated relaxation rates in high-resolution NMR spectroscopy.