Mapping the RNA binding sites for human immunodeficiency virus type-1 gag and NC proteins within the complete HIV-1 and -2 untranslated leader regions

Encapsidation of HIV-1 genomic RNA is mediated by specific interactions between the RNA packaging signal and the Gag protein. During maturation of the virion, the Gag protein is processed into smaller fragments, including the nucleocapsid (NC) domain which remains associated with the viral genomic RNA. We have investigated the binding of glutathione- S -transferase (GST) Gag and NC fusion proteins from HIV-1, to the entire HIV-1 and -2 leader RNAencompassing the packaging signal. We have mapped the binding sites at conditions where only about two complexes are formed and find that GST-Gag and GST-NC fusion proteins bind specifically to discrete sites within the leader. Analysis of the HIV-1 leader indicated that GST-Gag strongly associates with the PSI stem-loop and to a lesser extent with regions near the primer binding site. GST-NC binds the same regions but with reversed preferences. The HIV-1 proteins also interact specifically with the 5'-leader of HIV-2 and the major site of interaction mapped to a stem-loop, with homology to the HIV-1 PSI stem-loop structure. The different specificities of Gag and NC may reflect functionally distinct roles in the viral replication, and suggest that the RNA binding specificity of NC is modulated by its structural context.     

Major groove opening at the HIV-1 Tat binding site of TAR RNA evidenced by a rhodium probe

Transactivation of human immunodeficiency virus (HIV) gene expression requires the interaction of Tat protein with the trans-activation responsive region (TAR) RNA, a 59-base stem-loop structure located at the 5'-end of all mRNAs. The TAR RNA contains a six-nucleotide loop and a three-nucleotide pyrimidine bulge which separates two helical stem regions. The trinucleotide bulge is essential for high affinity and specific binding of the Tat protein. Recently, a rhodium complex, Rh(phen)2phi3+, was discovered which promotes RNA cleavage in the open major groove and triply bonded bases [Chow, C. S., et al. (1992) Biochemistry 31, 972-982]. This metal complex does not bind double-helical RNA or unstructured single-stranded regions of RNA. Instead, sites of tertiary interaction which are open in the major groove and accessible to stacking are targeted by the complex through photoactivated cleavage. We have used this rhodium probe to investigate the effect of bulge bases on the major groove opening in TAR RNA. The sites targeted by the rhodium complex have been mapped to single nucleotide resolution on wild-type TAR RNA and on several mutants of the TAR RNA containing different numbers of mismatch bases in the bulge region. A strong cleavage at residues C39 and U40 was observed on the wild-type TAR RNA and in mutant TAR RNA containing two mismatch bases in the bulge. No cleavage at C39 and U40 was observed in a bulgeless and a one-base bulge TAR RNA. By varying the number of mismatch bases, we demonstrated that the trinuclear bulge widens the major groove of TAR RNA to facilitate Tat binding.(ABSTRACT TRUNCATED AT 250 WORDS)     

The binding site of a specific aminoglycoside binding RNA molecule

A small (40 nucleotides) stem-loop derivative (J6f1) of a specific aminoglycoside-binding RNA aptamer, containing a 3 nt and a 1 nt bulge, has previously been shown to stoichiometrically bind tobramycin with a dissociation constant of approximately 5 nM [Hamasaki, K., Killian, J., Cho, J. and Rando, R. R. (1997) Biochemistry 36, 1367-1371]. This construct can strongly discriminate among similar aminoglycosides with respect to binding. A combination of chemical interference studies, chemical modification studies, and mutational studies are performed to define the aminoglycoside binding site of J6f1. Recognition of the aminoglycoside by J6f1 involves contacts with nucleotide bases, rather than with the phosphate backbone. The binding site 1 comprised of part of the stem-loop region. The two bulges are also essential for high affinity and stoichiometric binding of tobramycin. These bulges are probably important for prying open the double helical region, thereby allowing the aminoglycoside access to the nucleotide bases.     

Complementation of RNA binding site mutations in MS2 coat protein heterodimers

The coat protein of bacteriophage MS2 functions as a symmetric dimer to bind an asymmetric RNA hairpin. This implies the existence of two equivalent RNA binding sites related to one another by a 2-fold symmetry axis. In this view the symmetric binding site defined by mutations conferring the repressor-defective phenotype is a composite picture of these two asymmetric sites. In order to determine whether the RNA ligand interacts with amino acid residues on both subunits of the dimer and in the hope of constructing a functional map of the RNA binding site, we performed heterodimer complementation experiments. Taking advantage of the physical proximity of their N- and C-termini, the two subunits of the dimer were genetically fused, producing a duplicated coat protein which folds normally and allows the construction of the functional equivalent of obligatory heterodimers containing all possible pairwise combinations of the repressor-defective mutations. The restoration of repressor function in certain heterodimers shows that a single RNA molecule interacts with both subunits of the dimer and allows the construction of a functional map of the binding site.     

Crystal structure of the principal neutralization site of HIV-1

The crystal structure of a complex between a 24-amino acid peptide from the third variable (V3) loop of human immunodeficiency virus-type 1 (HIV-1) gp 120 and the Fab fragment of a broadly neutralizing antibody (59.1) was determined to 3 angstrom resolution. The tip of the V3 loop containing the Gly-Pro-Gly-Arg-Ala-Phe sequence adopts a double-turn conformation, which may be the basis of its conservation in many HIV-1 isolates. A complete map of the HIV-1 principal neutralizing determinant was constructed by stitching together structures of V3 loop peptides bound to 59.1 and to an isolate-specific (MN) neutralizing antibody (50.1). Structural conservation of the overlapping epitopes suggests that this biologically relevant conformation could be of use in the design of synthetic vaccines and drugs to inhibit HIV-1 entry and virus-related cellular fusion.     

Solution structure of the donor site of a trans-splicing RNA

The CYP51 gene encoding eburicol 14 alpha-demethylase (P450(14DM)) was cloned from a genomic library of the filamentous fungal plant pathogen Penicillium italicum, by heterologous hybridisation with the corresponding gene encoding lanosterol 14 alpha-demethylase from the yeast Candida tropicalis. The nucleotide sequence of a 1739-bp genomic fragment and the corresponding cDNA clone comprises an open reading frame (ORF) of 1545 bp, encoding a protein of 515 amino acids with a predicted molecular mass of 57.3 kDa. The ORF is interrupted by three introns of 60, 72 and 62 bp. The C-terminal part of the protein includes a characteristic haem-binding domain, HR2, common to all P450 genes. The deduced P. italicum P450(14DM) protein and the P450(14DM) proteins from Candida albicans, C. tropicalis and Saccharomyces cerevisiae share 47.2, 47.0 and 45.8% amino acid sequence identity. Therefore, the cloned gene is classified as a member of the CYP51 family. Multiple copies of a genomic DNA fragment of Pl italicum containing the cloned P450 gene were introduced into Aspergillus niger by transformation. Transformants were significantly less sensitive to fungicides which inhibit P450(14DM) activity, indicating that the cloned gene encodes a functional eburicol 14 alpha-demethylase.     

Structure-function analysis of the trypanosomatid spliced leader RNA

In trypanosomes, all mRNAs possess a spliced leader (SL) at their 5' end. SL is added to pre-mRNA via trans -splicing from a small RNA, the SL RNA. To examine structure-function aspects of the trypanosomatid SL RNA, an in vivo system was developed in the monogenetic trypanosomatid Leptomonas collosoma to analyze the function of chimeric and site-directed SL RNA mutants in trans -splicing. Stable cell lines expressing chimeric and mutated SL RNA from the authentic SL RNA regulatory unit were obtained. The chimeric RNA was expressed and assembled into an SL RNP particle, but could not serve as a substrate in splicing. Mutations in loop II and III of L.collosoma SL RNA formed the Y structure intermediate. In addition, a double SL RNA mutant in loop II, and positions 7 and 8 of the intron, also formed the Y structure intermediate, suggesting that these intron positions, although proposed to participate in the interaction of SL RNA with U5, may not be crucial for the first step of the trans -splicing reaction. A mutation in the exon located in loop I was not utilized in splicing, suggesting the importance of exon sequences for trans -splicing in trypanosomes. However, a double SL RNA mutant in loop II and exon position 31 was utilized in both steps of splicing; the mutant thus provides a model molecule for further analysis of positions essential for the function of the SL RNA.     

In vitro genetic analysis of the RNA binding site of vigilin, a multi-KH-domain protein

The function(s) and RNA binding properties of vigilin, a ubiquitous protein with 14 KH domains, remain largely obscure. We recently showed that vigilin is the estrogen-inducible protein in polysome extracts which binds specifically to a segment of the 3' untranslated region (UTR) of estrogen-stabilized vitellogenin mRNA. In order to identify consensus mRNA sequences and structures important in binding of vigilin to RNA, before vigilin was purified, we developed a modified in vitro genetic selection protocol. We subsequently validated our selection procedure, which employed crude polysome extracts, by testing natural and in vitro-selected RNAs with purified recombinant vigilin. Most of the selected up-binding mutants exhibited hypermutation of G residues leading to a largely unstructured, single-stranded region containing multiple conserved (A)nCU and UC(A)n motifs. All eight of the selected down-binding mutants contained a mutation in the sequence (A)nCU. Deletion analysis indicated that approximately 75 nucleotides are required for maximal binding. Using this information, we predicted and subsequently identified a strong vigilin binding site near the 3' end of human dystrophin mRNA. RNA sequences from the 3' UTRs of transferrin receptor and estrogen receptor, which lack strong homology to the selected sequences, did not bind vigilin. These studies describe an aproach to identifying long RNA binding sites and describe sequence and structural requirements for interaction of vigilin with RNAs.     

Non-canonical interactions in a kissing loop complex: the dimerization initiation site of HIV-1 genomic RNA

Retroviruses encapsidate two molecules of genomic RNA that are noncovalently linked close to their 5' ends in a region called the dimer linkage structure (DLS). The dimerization initiation site (DIS) of human immunodeficiency virus type 1 (HIV-1) constitutes the essential part of the DLS in vitro and is crucial for efficient HIV-1 replication in cell culture. We previously identified the DIS as a hairpin structure, located upstream of the major splice donor site, that contains in the loop a six-nucleotide self-complementary sequence preceded and followed by two and one purines, respectively. Two RNA monomers form a kissing loop complex via intermolecular interactions of the six nucleotide self-complementary sequence. Here, we introduced compensatory mutations in the self-complementary sequence and/or a mutation in the flanking purines. We determined the kinetics of dimerization, the thermal stabilities and the apparent equilibrium dissociation constants of wild-type and mutant dimers and used chemical probing to obtain structural information. Our results demonstrate the importance of the 5'-flanking purine and of the two central bases of the self-complementary sequence in the dimerization process. The experimental data are rationalized by triple interactions between these residues in the deep groove of the kissing helix and are incorporated into a three-dimensional model of the kissing loop dimer. In addition, chemical probing and molecular modeling favor the existence of a non-canonical interaction between the conserved adenine residues at the first and last positions in the DIS loop. Furthermore, we show that destabilization of the kissing loop complex at the DIS can be compensated by interactions involving sequences located downstream of the splice donor site of the HIV-1 genomic RNA.     

Major groove binding of the tRNA/mRNA complex to the 16 S ribosomal RNA decoding site

We propose a detailed three-dimensional model, with atomic detail, for the structure of the Escherichia coli 16 S rRNA decoding site in a complex with mRNA and the A and P-site tRNAs. Model building began with four primary assumptions: (1) A and P-site tRNA conformations are identical with those seen in the tRNA crystal structure; (2) A and P-site tRNAs adopt an S-type orientation upon binding mRNA in the ribosome; (3) A1492 and A1493 bind non-specifically to the mRNA through a series of hydrogen bonds; and (4) C1400 lies in close proximity to the P-site tRNA wobble base in order to satisfy a UV-induced photocrosslink formed between the two residues. We have models with both major groove and minor groove binding of the tRNA/mRNA complex to the decoding site RNA, and conclude that major groove binding is more likely. Both classes of models maintain structural features reported in the NMR structure of the A-site region of the decoding site RNA with bound paromomycin. We also present models for the tRNA/mRNA complex bound to the decoding site RNA in the presence of the aminoglycoside paromomycin. We discuss possible mechanisms for ribosomal proof reading and antibiotic disruption of this proofreading.     

Identification of determinants for inhibitor binding within the RNA active site of human telomerase using PNA scanning

Telomerase is a ribonucleoprotein that participates in the maintenance of telomere length. Its activity is up-regulated in many tumor types, suggesting that it may be a novel target for chemotherapy. The RNA component of telomerase contains an active site that plays at least two roles&sbd;binding telomere ends and templating their replication [Greider, C. W., & Blackburn, E. H. (1989) Nature 337, 331-337]. The accessibility of RNA nucleotides for inhibitor binding cannot be assumed because of the potential for RNA secondary structure and RNA-protein interactions. Here we use high-affinity recognition by overlapping peptide nucleic acids (PNAs) [Nielsen, P. E., et al. (1991) Science 254, 1497-1500] to identify nucleotides within the RNA active site of telomerase that are determinants for inhibitor recognition. The IC50 for inhibition decreases from 30 microM to 10 nM as cytidines 50-52 (C50-52) at the boundary between the alignment and elongation domains are recognized by PNAs overlapping from the 5' direction. As C50-52 are uncovered in the 3' direction, IC50 increases from 10 nM to 300 nM. As cytidine 56 at the extreme 3' end of the active site is uncovered, IC50 values increase from 0.5 microM to 10 microM. This analysis demonstrates that C50-C52 and C56 are important for PNA recognition and are physically accessible for inhibitor binding. We use identification of these key determinants to minimize the size of PNA inhibitors, and knowledge of these determinants should facilitate design of other small molecules capable of targeting telomerase. The striking differences in IC50 values for inhibition of telomerase activity by related PNAs emphasize the potential of PNAs to be sensitive probes for mapping complex nucleic acids. We also find that PNA hybridization is sensitive to nearest-neighbor interactions, and that consecutive guanine bases within a PNA strand increase binding to complementary DNA and RNA sequences.     

Ultrastructure of HIV-1 genomic RNA

The traditional acute care health care environment does not meet the needs of chronically ill patients and their families. The classic paternalistic approach encourages dependence on the health care team. This report reviews several innovative types of patient care delivery models, including patient-focused care, family-centered care, cooperative care, and Program Planetree. The core concepts of these various models are described and compared. Related research is presented. A synthesis of these existing models to meet the needs of chronically ill medical patients holistically is proposed. The implementation of the holistic model with chronically ill patients and their families is depicted.