Anwer Mujeeb

NMR structure of the mature dimer initiation complex of HIV-1 genomic RNA

The two identical genomic RNA strands inside each HIV‐1 viral particle are linked through homodimerization of an RNA stem‐loop, termed SL1, near their 5′ ends. SL1 first dimerizes through a palindromic sequence in its loop, forming a transient kissing‐loop complex which then refolds to a mature, linear duplex. We previously reported the NMR structure of a 23‐base truncate of SL1 in kissing‐dimer form, and here report the high‐resolution structure of its linear isoform. This structure comprises three short duplex regions – derived from the central palindrome and two stem regions of each strand, respectively – separated by two bulges that each encompass three unpaired adenines flanking the palindromes. The stacking pattern of these adenines differs from that seen in the kissing‐loop complex, and leads to greater colinear base stacking overall. Moreover, the mechanical distortion of the palindrome helix is reduced, and base pairs ruptured during formation of the kissing‐loop complex are re‐established, so that all potential Watson‐Crick pairs are intact. These features together likely account for the greater thermodynamic stability of the mature dimer as compared to its kissing‐loop precursor.

NMR Structure of the Full-length Linear Dimer of Stem-Loop-1 RNA in the HIV-1 Dimer Initiation Site

The packaging signal of HIV-1 RNA contains a stem-loop structure, SL1, which serves as the dimerization initiation site for two identical copies of the genome and is important for packaging of the RNA genome into the budding virion and for overall infectivity. SL1 spontaneously dimerizes via a palindromic hexanucleotide sequence in its apical loop, forming a metastable kissing dimer form. Incubation with nucleocapsid protein causes this form to refold to a thermodynamically stable mature linear dimer. Here, we present an NMR structure of the latter form of the full-length SL1 sequence of the Lai HIV-1 isolate. The structure was refined using nuclear Overhauser effect and residual dipolar coupling data. The structure presents a symmetric homodimer of two RNA strands of 35 nucleotides each; it includes five stems separated by four internal loops. The central palindromic stem is surrounded by two symmetric adenine-rich 1–2 internal loops, A-bulges. All three adenines in each A-bulge are stacked inside the helix, consistent with the solution structures of shorter SL1 constructs determined previously. The outer 4-base pair stems and, proximal to them, purine-rich 1–3 internal loops, or G-bulges, are the least stable parts of the molecule. The G-bulges display high conformational variability in the refined ensemble of structures, despite the availability of many structural restraints for this region. Nevertheless, most conformations share a similar structural motif: a guanine and an adenine from opposite strands form a GA mismatch stacked on the top of the neighboring stem. The two remaining guanines are exposed, one in the minor groove and another in the major groove side of the helix, consistent with secondary structure probing data for SL1. These guanines may be recognized by the nucleocapsid protein, which binds tightly to the G-bulge in vitro.

Molten-globule structure and membrane binding of the N-terminal protease-resistant domain (63-193) of the steroidogenic acute regulatory protein (StAR).

The first step in steroidogenesis is the movement of cholesterol from the outer to inner mitochondrial membrane; this movement is facilitated by the steroidogenic acute regulatory protein (StAR). StAR has molten-globule properties at low pH and a protease-resistant N-terminal domain at pH 4 and pH 8 comprising residues 63-193. To explore the mechanism of action of StAR we investigated the structural properties of the bacterially expressed N-terminal domain (63-193 StAR) using CD, limited proteolysis and NMR. Far- and near-UV CD showed that the amount of secondary structure was greater at acidic than at neutral pH, but there was little tertiary structure at any pH. Unlike 63-193 StAR liberated from N-62 StAR by proteolysis, biosynthetic 63-193 StAR was no longer resistant to trypsin or proteinase K at pH 7, or to pepsin at pH 4. Addition of trifluoroethanol and SDS increased secondary structure at pH 7, and dodecylphosphocholine and CHAPS increased secondary structure at pH 2, pH 4 and pH 7. However, none of these conditions induced tertiary structure, as monitored by near-UV CD or NMR. Liposomes of phosphatidylcholine, phosphatidylserine and their mixture increased secondary structure of 63-193 StAR at pH 7, as monitored by far-UV CD, and stable protein-liposome complexes were identified by gel-permeation chromatography. These results provide further evidence that the N-terminal domain of StAR is a molten globule, and provide evidence that this conformation facilitates the interaction of the N-terminal domain of StAR with membranes. We suggest that this interaction is the key to understanding the mechanism of StARs action.

The cyclobutane dimers of 5-methylcytosine and their deamination products

The photochemical reactions of 5-methylcytosine (m(5)C), a minor component of mammalian DNA, have been studied at a concentration of 2 mM in frozen 10 mM aqueous NaCl solution at dry ice temperature (194.5 K). For these studies, low-pressure lamps emitting mainly UVB radiation were used. We have isolated and characterized three cyclobutane dimers, namely the cis-anti(c,a) the cis-syn(c,s) and the trans-syn(t,s) forms. While the c,a and the t,s cyclobutane dimers are relatively stable towards deamination upon standing in solution at 277 K, the c,s isomer is gradually converted into the corresponding c,s m(5)C-thymine (Thy) mixed dimer; this latter reaction occurs considerably faster at 310 K. The t,s cyclobutane dimer is converted into the corresponding m(5)C-Thy mixed dimer upon incubation at 373 K, while the c,a dimer is converted into a mixture of m(5)C and c,a mixed dimer when incubated at 310 K. Irradiation of equimolar mixtures of Thy (1 mM) and m(5)C (1 mM) under similar conditions yields each of the three m(5)C cyclobutane dimers, as well as significant amounts of c,a, c,s and t,s m(5)C-Thy mixed cyclobutane dimers. These m(5)C-Thy dimers undergo decompositions similar in nature to the processes undergone by m(5)C cyclobutane dimers. Pseudo-first order rate constants for deamination of the c,s m(5)C homodimer and c,s m(5)C-Thy heterodimer at various temperatures and at pH 7.7 have been measured and the enthalpies and entropies of activation have been evaluated for the deamination processes for these two compounds. The two dimers have half-lives of about 14 and 22 h, respectively, at 310 K; however, at 273 K, the corresponding half-lives can be evaluated as being around 30 and 36 days, respectively.

Conformational dynamics in mixed α/β-oligonucleotides containing polarity reversals: A molecular dynamics study using time-averaged restraints*

Nucleic acid duplexes featuring a single alpha-anomeric thymidine inserted into each DNA strand via 3′-3′ and 5′-5′ phosphodiester linkages exhibit local conformational dynamics that are not adequately depicted by conventional restrained molecular dynamics (rMD) methods. We have used molecular dynamics with time-averaged NMR restraints (MDtar) to explore its applicability to describing the conformational dynamics of two α-containing duplexes – d(GCGAAT-3′-3′-αT-5′-5′-CGC)2 and d(ATGG-3′-3′-αT-5′-5′-GCTC)•r(gagcaccau). In contrast to rMD, enforcing NOE-based distance restraints over a period of time in MDtar rather than instantaneously results in better agreement with the experimental NOE and J-data. This conclusion is based on the dramatic decreases in average distance and coupling constant violations (Δdav, Jrms, and ΔJav) and improvements in sixth-root R-factors (Rx). In both duplexes, the deoxyribose ring puckering behavior predicted independently by pseudorotation analysis is portrayed remarkably well using this approach compared to rMD. This indicates that the local dynamic behavior is encoded within the NOE data, although this is not obvious from the local Rx values. In both systems, the backbone torsion angles comprising the 3′-3′ linkage as well as the (high S-) sugars of the α-nucleotide and preceding residue (α−1) are relatively static, while the conformations of the 5′-5′ linkage and the sugar in the neighboring β-nucleotide (α+1) show enhanced flexibility. To reduce the large ensembles generated by MDtar to more manageable clusters we utilized the PDQPRO program. The resulting PDQPRO clusters (in both cases, 13 structures and associated probabilities extracted from a pool of 300 structures) adequately represent the structural and dynamic characteristics predicted by the experimental data.

A Small Molecule, Lys-Ala-7-amido-4-methylcoumarin, Facilitates RNA Dimer Maturation of a Stem-Loop 1 Transcript in Vitro : Structure-Activity Relationship of the Activator

The type 1 human immunodeficiency virus (HIV-1), like all retroviruses, contains two copies of the RNA genome as a dimer. A dimer initially forms via a self-complementary sequence in the dimer initiation site (DIS) of the genomic RNA, but that dimer is converted to a mature dimer in a process generally promoted by the viral nucleocapsid (NC) protein. Formation of the mature dimer is correlated with infectivity. Study of genomic dimerization has been facilitated by discovery of short RNA transcripts containing the DIS stem-loop 1 (SL1), which can dimerize spontaneously without any protein factors in vitro as well as via the NC protein. On the basis of the palindromic nature of the apical loop of SL1, a kissing loop model has been proposed. First, a metastable kissing dimer is formed via a loop-loop interaction and then converted into a more stable extended dimer by the NC protein. This dimerization process in vitro is believed to mimic the in vivo RNA maturation. During experimental screening of potential inhibitors, we discovered a small molecule, Lys-Ala-7-amido-4-methylcoumarin (KA-AMC), which facilitates the in vitro conversion from kissing dimer to extended dimer. Here we report the structure-activity relationship for KA-AMC for promoting dimer maturation. Guanidino groups and increasing positive charge on the side chain enhance activity. For activity, the charged side chain is preferred on the benzene ring, and O 1 in the coumarin scaffold is essential. NMR studies show that the coumarin derivatives stack with aromatic bases of the RNA. The coumarin derivatives may aid in the investigation of some aspects of dimer maturation and serve as a scaffold for design of maturation inhibitors or of activators of premature maturation, either of which can lead to a potential HIV therapeutic.

AQUEOUS SOLUTION STRUCTURE OF A HYBRID LENTIVIRAL TAT PEPTIDE AND A MODEL OF ITS INTERACTION WITH HIV-1 TAR RNA

Human immunodeficiency virus, type 1, (HIV-1) encodes a transactivating regulatory protein, called Tat, which is required for efficient transcription of the viral genome. Tat acts by binding to a specific RNA stem-loop element, called TAR, on nascent viral transcripts. The specificity of binding is principally determined by residues in a short, highly basic domain of Tat. The structure in aqueous solution of a biologically active peptide, comprised of the ten-amino acid HIV-1 Tat basic domain linked to a 15-amino acid segment of the core regulatory domain of another lentiviral Tat, i.e., that from equine infectious anemia virus (EIAV), has been determined. The restraint data set includes interproton distance bounds determined from two-dimensional nuclear Overhauser effect (2D NOE) spectra via a complete relaxation matrix analysis. Thirty structures consistent with the experimental data were generated via the distance geometry program DIANA. Subsequent restrained molecular mechanics calculations were used to define the conformational space subtended by the peptide. A large fraction of the 25-mer peptide assumes a structure in aqueous solution with the lysine- and arginine-rich HIV-1 basic domain being separated from the basic domain by a turn and characterized by a nascent helix as well. The Tat peptide/TAR complex could be modeled with the basic alpha-helix lying in the major groove of TAR such that important interactions of a putative specificity-endowing arginine are maintained and very slight widening of the major groove is entailed.

Three-dimensional RNA structure-based drug discovery.

Abstract We have initiated a program to develop promising drug candidate leads using a new drug discovery paradigm based on three-dimensional RNA-structure-based computational screening of about 200,000 commercially available compounds for binding to selected RNA targets. As our first endeavor, we are using the three-dimensional structure of portions of the HIV-1 genome. Candidate lead compounds we seek are water-soluble, nonpeptide, nonnucleotide organic compounds generally with molecular weight less than 500 daltons. Structural studies of complexes formed with potential leads and their RNA targets should eventually yield insight into features governing affinity and specificity. The promising leads identified by virtual screening are tested for inhibition in functional assays. Leads will be selected for further development via computational and experimental combinatorial chemistry.

Determination of High-Resolution, Sequence-Dependent DNA Duplex Structures in Solution

There can be rather subtle structural variations in the DNA double helix which are sequence-dependent; but these subtle structural differences may direct protein, mutagen or drug recognition. These subtle variations demand detailed knowledge of the structure. This has not been easy to achieve, but the ability to determine an accurate, high-resolution structure of nearly any DNA double helix of length less than 15 base pairs (bp) is now possible if sufficient care and effort are expended. The structure of any molecule can be determined with a sufficient number of structural restraints, e.g., internuclear distances and bond torsion angles, in conjunction with holonomic constraints of bond lengths, bond angles, and steric limitations. NMR, in conjunction with appropriate computational algorithms, has become the method of choice for determination of the high-resolution solution structure of proteins, nucleic acids and complexes. Multidimensional NMR has the capability of yielding interpro- ton distances and bond torsion angles as experimental structural restraints (James and Basus, 1991; Oppenheimer and James, 1989; Wagner et al, 1992). These structural restraints per se do not constitute a structure. However, use of algorithms, such as distance geometry (DG) and restrained molecular dynamics (rMD), which search conformational space to define structures consistent with the experimental restraints will provide a “structure” or envelope of closely related structures. Structure determination via NMR is distinctly different from the situation with x-ray crystallographic determination of structure, where Fourier transformation of the diffraction pattern basically yields an atomic array (assuming the phase problem has been solved).