Identification of amino acids that promote specific and rigid TAR RNA-tat protein complex formation

The Tat protein and the transactivation responsive (TAR) RNA form an essential complex in the HIV lifecycle, and mutations in the basic region of the Tat protein alter this RNA-protein molecular recognition. Here, EPR spectroscopy was used to identify amino acids, flanking an essential arginine of the Tat protein, which contribute to specific and rigid TAR-Tat complex formation by monitoring changes in the mobility of nitroxide spin-labeled TAR RNA nucleotides upon binding. Arginine to lysine N-terminal mutations did not affect TAR RNA interfacial dynamics. In contrast, C-terminal point mutations, R56 in particular, affected the mobility of nucleotides U23 and U38, which are involved in a base-triple interaction in the complex. This report highlights the role of dynamics in specific molecular complex formation and demonstrates the ability of EPR spectroscopy to study interfacial dynamics of macromolecular complexes.     

Distance Measurement on an Endogenous Membrane Transporter in E. coli Cells and Native Membranes Using EPR Spectroscopy

Membrane proteins may be influenced by the environment, and they may be unstable in detergents or fail to crystallize. As a result, approaches to characterize structures in a native environment are highly desirable. Here, we report a novel general strategy for precise distance measurements on outer membrane proteins in whole Escherichia coli cells and isolated outer membranes. The cobalamin transporter BtuB was overexpressed and spin‐labeled in whole cells and outer membranes and interspin distances were measured to a spin‐labeled cobalamin using pulse EPR spectroscopy. A comparative analysis of the data reveals a similar interspin distance between whole cells, outer membranes, and synthetic vesicles. This approach provides an elegant way to study conformational changes or protein–protein/ligand interactions at surface‐exposed sites of membrane protein complexes in whole cells and native membranes, and provides a method to validate outer membrane protein structures in their native environment.     

Investigation of RNA-protein and RNA-metal ion interactions by electron paramagnetic resonance spectroscopy. The HIV TAR-Tat motif

Electron paramagnetic resonance (EPR) spectroscopy was used to investigate changes in dynamics of spin-labeled nucleotides in the TAR RNA (U23, U25, U38, and U40) upon binding to cations, argininamide, and two peptides derived from the Tat protein. Nearly identical changes in dynamics were obtained for either calcium or sodium ions, indicating the absence of a calcium-specific structural change for the TAR RNA in solution that had previously been suggested by crystallographic data. Similar dynamic signatures were obtained for two Tat-derived peptides that have the same important binding determinant (R52) and similar binding affinities to the TAR RNA. However, U23 and U38 were substantially less mobile for the wild-type peptide (YGRKKRRQRRR) than for the mutant (YKKKKRKKKKA), demonstrating that, flanking R52, amino acids in the wild-type sequence make specific contacts to the RNA.     

Measurement of the effect of monovalent cations on RNA hairpin stability

Using optical tweezers, we have measured the effect of monovalent cation concentration and species on the folding free energy of five large (49-124 nt) RNA hairpins, including HIV-1 TAR and molecules approximating A.U and G.C homopolymers. RNA secondary structure thermodynamics are accurately described by a model consisting of nearest-neighbor interactions and additive loop and bulge terms. Melting of small (<15 bp) duplexes and hairpins in 1 M NaCl has been used to determine the parameters of this model, which is now used extensively to predict structure and folding dynamics. Few systematic measurements have been made in other ionic conditions or for larger structures. By applying mechanical force, we measured the work required to fold and unfold single hairpins at room temperature over a range of cation concentrations from 50 to 1000 mM. Free energies were then determined using the Crooks fluctuation theorem. We observed the following: (1) In most cases, the nearest-neighbor model accurately predicted the free energy of folding at 1 M NaCl. (2) Free energy was proportional to the logarithm of salt concentration. (3) Substituting potassium ions for sodium slightly decreased hairpin stability. The TAR hairpin also misfolded nearly twice as often in KCl, indicating a differential kinetic response. (4) Monovalent cation concentration affects RNA stability in a sequence-dependent manner. G.C helices were unaffected by changing salt concentration, A.U helices were modestly affected, and the hairpin loop was very sensitive. Surprisingly, the U.C.U bulge of TAR was found to be equally stable in all conditions tested. We also report a new estimate for the elastic parameters of single-stranded RNA.     

Determination of intermolecular copper–copper distances from the EPR half-field transitions and their comparison with distances from X-ray structures: applications to copper(II) complexes with biologically important ligands

An EPR method involving measurement of half-field transitions was applied to determine the intermolecular Cu–Cu distances in copper(II)-carboxylate complexes with biologically important ligands. The experimental powder EPR spectra are composed of allowed (ΔM _S  = ±1) transitions centered at ~3,200 Gauss and of weak intensity, nominally forbidden, half-field (ΔM _S  = ±2) peaks observable at ~1,600 Gauss. Values of the average interspin distance for each complex were determined from the ratios of integrated allowed and forbidden peak areas using each of several methods. The calculated interspin distances were correlated with the copper–copper distances experimentally obtained by X-ray crystallography. The distances determined from the EPR spectra agree well with the X-ray determined values when the crystallographic value for one member of a series is used to calibrate the series. Less satisfactory agreement is found when methods based on Cu-spin-label systems are used.     

Studying aminoglycoside antibiotic binding to HIV-1 TAR RNA by electrospray ionization mass spectrometry

The recognition of the aminoglycosides neomycin and streptomycin by HIV-1 TAR RNA was studied by electrospray ionization mass spectrometry (ESI-MS). Members of the aminoglycoside family of antibiotics are known to target a wide variety of RNA molecules. Neomycin and streptomycin inhibit the formation of the Tat protein–TAR RNA complex, an assembly that is believed to be necessary for HIV replication. The noncovalent complexes formed by the binding of aminoglycosides to TAR RNA and the Tat–TAR complex were detected by ESI-MS. Neomycin has a maximum binding stoichiometry of three and two to TAR RNA and to the Tat–TAR complex, respectively. Data from the ESI-MS experiments suggest that a high affinity binding site of neomycin is located near the three-nucleotide bulge region of TAR RNA. This is consistent with previous solution phase footprinting measurements [H.-Y. Mei et al., Biochemistry 37 (1998) 14204]. Neomycin has a higher affinity toward TAR RNA than streptomycin, as measured by ESI-MS competition binding experiments. A noncovalent complex formed between a small molecule inhibitor of TAR RNA, which has a similar solution binding affinity as the aminoglycosides, and TAR RNA is much less stable than the RNA–aminoglycoside complexes to collisional dissociation in the gas phase. It is believed that the small molecule inhibitor interacts with TAR RNA via hydrophobic interactions, whereas the aminoglycosides bind to RNAs through electrostatic forces. This difference in gas phase stabilities may prove useful for discerning the types of noncovalent forces holding complexes together.     

Design and Synthesis of Guanidinoglycosides Directed against the TAR RNA of HIV‐1

Replication of human immunodeficiency virus type 1 (HIV‐1) requires specific interactions of the Tat protein with the transactivation responsive region (TAR) RNA. Tat‐TAR RNA Interaction is mediated by a short arginine‐rich domain of the protein. Disruption of this interaction could, in theory, create a state of complete viral latency. Here, four novel 6‐amino‐6‐deoxytrehalose guanidinoglycoside derivatives ( 10 and 13 – 15 ) as target molecules have been designed to bind to TAR RNA for blocking the interaction of Tat‐TAR RNA. They were obtained by coupling 6‐amino‐6‐deoxy‐α,α‐trehalose ( 6 ) with the protected amino acids, deprotection by catalytic hydrogenation, followed by guanidinylated with S‐methylisothiourea sulfate. Their abilities to inhibit Tat‐TAR RNA interaction were determined by a Tat‐dependent HIV‐1 long terminal repeats (LTR)‐driven chloramphenicol acetyltransferase (CAT) assays.     

Influence of metal coordination on the mismatch tolerance of ligand-modified PNA duplexes

Recent studies on metal incorporation in ligand-modified nucleic acids have focused on the effect of metal coordination on the stability of metal-containing duplexes or triplexes and on the metal binding selectivity but did not address the effect of the sequence of the nucleic acid in which the ligands are incorporated. We have introduced 8-hydroxyquinoline Q in 10-mer PNA strands with various sequences and have investigated the properties of the duplexes formed from these strands upon binding of Cu(2+). Variable-temperature UV-vis spectroscopy shows that, in the presence of Cu(2+), duplexes are formed even from ligand-modified Q-PNA strands that have a large number of mismatches. Spectrophotometric titrations demonstrate that at any temperature, one Cu(2+) ion binds a pair of Q-PNA strands that each contain one 8-hydroxyquinoline, but below the melting temperature, the PNA duplex exerts a supramolecular chelate effect, which prevents the transformation in the presence of excess Cu(2+) of the 1:2 Cu(2+):Q-PNA complexes into 1:1 complexes. EPR spectroscopy gives further support for the existence in the duplexes of [CuQ(2)] moieties that are similar to the corresponding square planar synthetic complex formed between Cu(2+) and 8-hydroxyquinoline. As PNA duplexes show a preferred handedness due to the chiral induction effect of a C-terminal l-lysine, which is transmitted through stacking interactions within the duplex, only if the metal-containing duplex has complementary strands, does it show a chiral excess measured by CD spectroscopy. The strong effect of the metal-ligand moiety is suggestive of an increased correlation length in PNA duplexes that contain such moieties. These results indicate that strong metal-ligand alternative base pairs significantly diminish the importance of Watson-Crick base pairing for the formation of a stable PNA duplex and lead to high mismatch tolerance, a principle that can be used in the construction of hybrid inorganic-nucleic acid nanostructures.     

Impact of electron-electron spin interaction on electron spin relaxation of nitroxide diradicals and tetraradical in glassy solvents between 10 and 300 k

To determine the impact of electron-electron spin-spin interactions on electron spin relaxation rates, 1/T1 and 1/Tm were measured for nitroxide monoradical, diradical, and tetraradical derivatives of 1,3-alternate calix[4]arenes, for two pegylated high-spin nitroxide diradicals, and for an azine-linked nitroxide diradical. The synthesis and characterization by SQUID (superconducting quantum interference device) magnetometry of one of the high-spin diradicals, in which nitroxides are conformationally constrained to be coplanar with the m-phenylene unit, is reported. The interspin distances ranged from about 5-9 A, and the magnitude of the exchange interaction ranged from >150 to >0.1 K. 1/T1 and 1/Tm were measured by long-pulse saturation recovery, three-pulse inversion recovery, and two-pulse echo decay at X-band (9.5 GHz) and Q-band (35 GHz). For a diradical with interspin distance about 9 A, relaxation rates were only slightly faster than for a monoradical with analogous structure. For interspin distances of about 5-6 A, relaxation rates in glassy solvents up to 300 K increased in the order monoradical < diradical < tetraradical. Modulation of electron-electron interaction enhanced relaxation via the direct, Raman, and local mode processes. The largest differences in 1/T1 were observed below 10 K, where the direct process dominates. For the three diradicals with comparable magnitude of dipolar interaction, 1/Tm and 1/T1 were faster for the molecules with more flexible structures. Relaxation rates were faster in the less rigid low-polarity sucrose octaacetate glass than in the more rigid 4:1 toluene/chloroform or in hydrogen-bonded glycerol glasses, which highlights the impact of motion on relaxation.     

A suite of 2H NMR spin relaxation experiments for the measurement of RNA dynamics

A suite of (2)H-based spin relaxation NMR experiments is presented for the measurement of molecular dynamics in a site-specific manner in uniformly (13)C, randomly fractionally deuterated ( approximately 50%) RNA molecules. The experiments quantify (2)H R(1) and R(2) relaxation rates that can subsequently be analyzed to obtain information about dynamics on a pico- to nanosecond time scale. Sensitivity permitting, the consistency of the data can be evaluated by measuring all five rates that are accessible for a spin 1 particle and establishing that the rates obey relations that are predicted from theory. The utility of the methodology is demonstrated with studies of the dynamics of a 14-mer RNA containing the UUCG tetraloop at temperatures of 25 and 5 degrees C. The high quality of the data, even at 5 degrees C, suggests that the experiments will be of use for the study of RNA molecules that are as large as 30 nucleotides.     

Duplex formation and the onset of helicity in poly d(CG)n oligonucleotides in a solvent-free environment

The gas-phase conformations of a series of cytosine/guanine DNA duplexes were examined by ion mobility and molecular dynamics methods. Deprotonated duplex ions were formed by electrospray ionization, and their collision cross sections measured in helium were compared to calculated cross sections of theoretical models generated by molecular dynamics. The 4-mer (dCGCG) and 6-mer (dCGCGCG) duplexes were found to have globular conformations. Globular and helical structures were observed for the 8-mer (dCGCGCGCG) duplex, with the globular form being the more favored conformer. For the 10-mer (dCGCGCGCGCG), 14-mer (dCGCGCGCGCGCGCG), and 18-mer (dCGCGCGCGCGCGCGCGCG) duplexes, only helical structures were observed in the ion mobility measurements. Theory predicts that the helical structures are less stable than the globular forms in the gas phase and should collapse into the globular form given enough time. However, molecular dynamics simulations at 300 K indicate the helical structures are stable in aqueous solution and will retain their conformations for a limited time in the gas phase. The presence of helical structures in the ion mobility experiments indicates that the duplexes retain "solution structures" in the gas phase on the millisecond time scale.     

MoV electron paramagnetic resonance of sulfite oxidase revisited: the low-pH chloride signal

Valuable information on the active sites of molybdenum enzymes has been provided by Mo(V) electron paramagnetic resonance (EPR) spectroscopy. In recent years, multiple resonance techniques have been extensively used to examine details of the active-site structure, but basic continuous-wave (CW) EPR has not been re-evaluated in several decades. Here, we present a re-examination of the CW EPR spectroscopy of the sulfite oxidase low-pH chloride species and provide evidence for direct coordination of molybdenum by chloride.     

Mapping the interaction forces between TAR RNA and TAT peptides on GaAs surfaces using chemical force microscopy

The complexation of the HIV transactivation response element (TAR) RNA with the viral regulatory protein TAT is of enormous interest for the design of new sensing and therapeutic strategies. In this work, we anchored TAT peptides on GaAs surfaces using microcontact printing. Atomic force microscopy was used to quantify the interaction between TAR RNA and model TAT peptide sequences. Different pH conditions were utilized in order to assess specific vs nonspecific interactions. AFM tips functionalized with TAR RNA molecules were used to collect adhesion maps that displayed stronger interaction with peptide sequences that contained a greater number of arginine residues. All of the studies consistently showed a pH dependence of the interaction between the surface bound peptides and the TAR RNA on the AFM tips. This work quantifies the TAR RNA/TAT peptide interaction after one of the molecules is anchored on a surface. The conclusions in this paper are consistent with previous work and demonstrate that cationic residues are responsible for the polyelectrolyte-like affinity of TAT peptides for TAR RNA.     

Native Top‐Down Mass Spectrometry of TAR RNA in Complexes with a Wild‐Type tat Peptide for Binding Site Mapping

Ribonucleic acids (RNA) frequently associate with proteins in many biological processes to form more or less stable complex structures. The characterization of RNA–protein complex structures and binding interfaces by nuclear magnetic resonance (NMR) spectroscopy, X‐ray crystallography, or strategies based on chemical crosslinking, however, can be quite challenging. Herein, we have explored the use of an alternative method, native top‐down mass spectrometry (MS), for probing of complex stoichiometry and protein binding sites at the single‐residue level of RNA. Our data show that the electrostatic interactions between HIV‐1 TAR RNA and a peptide comprising the arginine‐rich binding region of tat protein are sufficiently strong in the gas phase to survive phosphodiester backbone cleavage of RNA by collisionally activated dissociation (CAD), thus allowing its use for probing tat binding sites in TAR RNA by top‐down MS. Moreover, the MS data reveal time‐dependent 1:2 and 1:1 stoichiometries of the TAR–tat complexes and suggest structural rearrangements of TAR RNA induced by binding of tat peptide.     

Structure-based computational database screening, in vitro assay, and NMR assessment of compounds that target TAR RNA

There has been little prior effort to discover new drugs on the basis of a unique RNA structure. Binding of the viral transactivator Tat to the 5' bulge of the transactivation response (TAR) element is necessary for HIV-1 replication, so TAR RNA is a superb target. A computational approach was developed to screen a large chemical library for binding to a three-dimensional RNA structure. Scoring function development, flexible ligand docking, and limited target flexibility were essential. From the ranked list of compounds predicted to bind TAR, 43 were assayed for inhibition of the Tat-TAR interaction via electrophoretic mobility shift assays. Eleven compounds (between 0.1 and 1 microM) inhibited the Tat-TAR interaction, and some inhibited Tat transactivation in cells. NMR spectra verified specific binding to the 5' bulge and no interaction with other regions of TAR.     

Theoretical analysis of antisense duplexes: determinants of the RNase H susceptibility

The structure and dynamic properties of different antisense related duplexes (DNA x RNA, 2'O-Me-DNA x RNA, 2'F-ANA x RNA, C5(Y)-propynyl-DNA x RNA, ANA x RNA, and control duplexes DNA x DNA and RNA x RNA) have been determined by means of long molecular dynamics simulations (covering more than 0.5 micros of fully solvated unrestrained MD simulation). The massive analysis presented here allows us to determine the subtle differences between the different duplexes, which in all cases pertain to the same structural family. This analysis provides information on the molecular determinants that allow RNase H to recognize and degrade some of these duplexes, whereas others with apparently similar conformations are not affected. Subtle structural and deformability features define the key properties used by RNase H to discriminate between duplexes.