Aminoglycoside binding in the major groove of duplex RNA: the thermodynamic and electrostatic forces that govern recognition

We use a combination of spectroscopic, calorimetric, viscometric and computer modeling techniques to characterize the binding of the aminoglycoside antibiotic, tobramycin, to the polymeric RNA duplex, poly(rI).poly(rC), which exhibits the characteristic A-type conformation that is conserved among natural and synthetic double-helical RNA sequences. Our results reveal the following significant features: (i) CD-detected binding of tobramycin to poly(rI).poly(rC) reveals an apparent site size of four base-pairs per bound drug molecule; (ii) tobramycin binding enhances the thermal stability of the host poly(rI).poly(rC) duplex, the extent of which decreases upon increasing in Na(+) concentration and/or pH conditions; (iii) the enthalpy of tobramycin- poly(rI).poly(rC) complexation increases with increasing pH conditions, an observation consistent with binding-induced protonation of one or more drug amino groups; (iv) the affinity of tobramycin for poly(rI).poly(rC) is sensitive to both pH and Na(+) concentration, with increases in pH and/or Na(+) concentration resulting in a concomitant reduction in binding affinity. The salt dependence of the tobramycin binding affinity reveals that the drug binds to the host RNA duplex as trication. (v) The thermodynamic driving force for tobramycin- poly(rI).poly(rC) complexation depends on pH conditions. Specifically, at pH< or =6.0, tobramycin binding is entropy driven, but is enthalpy driven at pH > 6.0. (vi) Viscometric data reveal non-intercalative binding properties when tobramycin complexes with poly(rI).poly(rC), consistent with a major groove-directed mode of binding. These data also are consistent with a binding-induced reduction in the apparent molecular length of the host RNA duplex. (vii) Computer modeling studies reveal a tobramycin-poly(rI). poly(rC) complex in which the drug fits snugly at the base of the RNA major groove and is stabilized, at least in part, by an array of hydrogen bonding interactions with both base and backbone atoms of the host RNA. These studies also demonstrate an inability of tobramycin to form a stable low-energy complex with the minor groove of the poly(rI).poly(rC) duplex. In the aggregate, our results suggest that tobramycin-RNA recognition is dictated and controlled by a broad range of factors that include electrostatic interactions, hydrogen bonding interactions, drug protonation reactions, and binding-induced alterations in the structure of the host RNA. These modulatory effects on tobramycin-RNA complexation are discussed in terms of their potential importance for the selective recognition of specific RNA structural motifs, such as asymmetric internal loops or hairpin loop-stem junctions, by aminoglycoside antibiotics and their derivatives.     

A method for isolation of oligo(uridylic acid)-containing messenger ribonucleic acid from HeLa cells

When cytoplasmic polyadenylated ribonucleic acid [poly(A+)RNA] from HeLa cells was treated with ribonuclease H (RNase H) and oligodeoxythymidylate [oligo(dT)] to remove its 3'-poly(A) tail, an increased binding to poly(A)-agarose was observed. The bound material, which comprised 4-6% of the initial RNA, contained 65-80% of the oligo(uridylic acid) [oligo(U)] sequences generated by RNase T1 digestion. Oligo(U) isolated from the bound fraction was shown to be 83% U and to have a U/G ratio of 33. In contrast, oligo(U) from the unbound material was 77% U and had a U/G ratio of 13, suggesting that it is shorter and less U rich than the oligo(U) in the bound fraction. On sucrose gradients, oligo(U+)RNA consistently sedimented with a larger s value than oligo(U-) RNA. The oligo(U) content of oligo(U+) RNA suggests one oligo(U) tract of 33 nucleotides per RNA molecule of 2000-3000 residues.     

Differential accumulation of two size classes of poly(A) associated with messenger RNA during oogenesis in Xenopus laevis

The RNA of full-grown oocytes of Xenopus laevis contains two distinct size classes of poly(A), designated poly(A)_S and poly(A)_L, which contain 15–30 (mean = 20) and 40–80 (mean = 61) A residues, respectively. Both poly(A)_L and poly(A)_S are associated with RNA which is heterogeneous in size. The two classes of poly(A)⁺ RNA can be separated by affinity chromatography: Only poly(A)_L⁺ RNA binds to oligo(dT)-cellulose under appropriate conditions, but up to 50% of the poly(A)_S⁺ RNA can be isolated from the void fraction by binding to poly(U)-Sepharose. Both classes of poly(A)⁺ RNA are active as messenger RNA in an in vitro system and yield identical patterns of in vitro protein products. Previtellogenic oocytes contain almost exclusively poly(A)_L, which accumulates up to vitellogenesis but remains almost constant in amount (molecules/oocyte) during vitellogenesis and in the full-grown oocyte. Poly(A)_S accumulates (molecules/oocyte) from early vitellogenesis up to the full-grown oocyte. The total number of poly(A)⁺ RNA molecules per oocyte increases throughout oogenesis from 2 × 10¹⁰/previtellogenic oocyte [80–90% poly(A)_L] to 20 × 10¹⁰/full-grown oocyte (25–40% poly(A)_L). It is argued that poly(A)_S is protected from degradation in the oocyte, thus stabilizing the “maternal” poly(A)⁺ mRNA.     

Isolation of poly(A)+ RNA by paper affinity chromatography

Poly(A)+ RNA was isolated from in vitro short-term-labeled total cytoplasmic RNA of Ehrlich ascites tumor cells by oligo(dT) cellulose chromatography. This poly(A)+ RNA fraction was compared with a poly(A)+ RNA fraction isolated by a new procedure which involves specific binding of poly(A)+ RNA to messenger affinity paper (mAP) and its release in hot (70 degrees C) water. In typical experiments 10-11 micrograms (2.3%) of poly(A)+ RNA can be retained from 500 micrograms of total cytoplasmic RNA per cm2 of mAP in a quick one-step procedure. The poly(A)+ RNA preparations isolated by the two methods proved to be almost identical with respect to their fraction in total cytoplasmic RNA, specific radioactivities, sucrose gradient profiles, and translation assays. Since the isolation of poly(A)+ RNA by mAP is much less time consuming than that by oligo(dT) column chromatography and since the poly(A)+ RNA can be recovered from mAP in small volumes, which avoids further loss during precipitations, it can be advantageously used for preparative isolation of poly(A)+ RNA.     

The structure of pre-messenger RNA and messenger RNA from erythroid cells

Pre-mRNA fractions (greater than 45 S) were characterized by electron microscopy. High salt concentrations (0.2 M ammonium acetate, pH 8) yield linear molecules of different length (0.5--17 micrometer). In 10% of the molecules a compact-nonlinear contour (cn-contour) is detectable at one end. A significant enhancement of the number of cn-contour carrying molecules is observed after binding pre-mRNA to poly(U)-sepharose. The terminal cn-contour could be the depiction of a secondary and/or tertiary structure including the poly(A)-tail. 9 S globin mRNA appear in 80% with virtually the same cn-contour as detected in pre-mRNA molecules. After denaturing the mRNA in 80% formamide--4M urea in connection with heating to 90 degrees C from 10 min, a percentage of 77% of stretched, linear molecules results. This structural transformation is reversible when the denatured RNA is precipitated and redissolved in 0.2 M ammonium acetate. 73% of the stretched molecules are characterized by a mean length of 0.44 micrometer. This value is twice as high as commonly assumed for a globin mRNA chain.     

Antibacterial nitroacridine, Nitroakridin 3582: binding to nucleic acids in vitro and effects on selected cell-free model systems of macromolecular biosynthesis

Nitroakridin 3582 (NA) formed complexes with native deoxyribonucleic acid (DNA) and with transfer ribonucleic acid (tRNA) species from Escherichia coli. Spectrophotometric titrations of NA with these nucleic acids produced numerical results from which nonlinear adsorption isotherms were derived. These curves indicated the existence of more than one class of binding sites on the polymers to which NA was bound by more than one process. The stoichiometry of strong binding of NA to double helical DNA was in agreement with a conventional value (1 ligand molecule per 4.2 component nucleotides) for complete intercalation binding. NA inhibited the DNA-dependent DNA polymerase I and RNA polymerase reactions, the first strongly and the second appreciably. These inhibitions corresponded to the extents to which NA inhibits DNA and RNA biosyntheses in vivo. Evidently, NA interferes with the template function of DNA. The drug also inhibited the polymerization of phenylalanine in a cell-free E. coli ribosome-polyuridylic acid [poly (U)] system. The effect paralleled an inhibition of the poly (U)-directed binding of phenylalanyl tRNA to ribosomes. Ethidium bromide acted similarly. The antimalarial drug, chloroquine, stimulated polyphenylalanine synthesis, apparently as a result of stimulating the poly (U)-directed binding of phenylalanyl tRNA to ribosomes.     

Sequence complexity of poly(A) RNA fromPhysarum polycephalum

Summary Poly(A) RNA from S phase, G₂ phase and starved macroplasmodia of Physarum contain mRNA sequences which when translated in vitro, yield similar patterns of polypeptides after fluorography.Reassociation of nick-translated DNA (Cot) allows the isolation of highly labeled single copy DNA which, after saturation hybridization with poly(A) RNA, gives values of 23% for growth and 17% for starvation.Homologous cDNA/poly(A) RNA hybridization reactions (Rot) indicate that 22–28% of the genome is transcribed during growth and 12% during starvation and that about half of the cDNA reacts with 0.1% of the genome and could represent 50–80 RNA species, each present in about 1,000 copies per nucleus. Up to 25,000 different RNA species, 1–5 copies each per nucleus, are estimated to be present during growth, and about 15,000 during starvation. Heterologous cDNA/poly(A) RNA hybridization reactions (Rot) indicate that the RNA sequences in S and G₂ phase of the cell cycle are similar, with RNA sequences being more abundant in G₂ phase.During starvation about 25% of the sequences present during growth cannot be detected and those sequences present during growth have become diluted during starvation.     

The RNA binding domains of the nuclear poly(A)-binding protein

The nuclear poly(A)-binding protein (PABPN1) is involved in the synthesis of the mRNA poly(A) tails in most eukaryotes. We report that the protein contains two RNA binding domains, a ribonucleoprotein-type RNA binding domain (RNP domain) located approximately in the middle of the protein sequence and an arginine-rich C-terminal domain. The C-terminal domain also promotes self-association of PABPN1 and moderately cooperative binding to RNA. Whereas the isolated RNP domain binds specifically to poly(A), the isolated C-terminal domain binds non-specifically to RNA and other polyanions. Despite this nonspecific RNA binding by the C-terminal domain, selection experiments show that adenosine residues throughout the entire minimal binding site of approximately 11 nucleotides are recognized specifically. UV-induced cross-links with oligo(A) carrying photoactivatable nucleotides at different positions all map to the RNP domain, suggesting that most or all of the base-specific contacts are made by the RNP domain, whereas the C-terminal domain may contribute nonspecific contacts, conceivably to the same nucleotides. Asymmetric dimethylation of 13 arginine residues in the C-terminal domain has no detectable influence on the interaction of the protein with RNA. The N-terminal domain of PABPN1 is not required for RNA binding but is essential for the stimulation of poly(A) polymerase.     

Interaction of sanguinarine with double stranded RNA structures

Interaction of sanguinarine with A-form RNA structures of poly(rI)poly(rC) and poly(rA).poly(rU) has been studied by spectrophotometric, spectrofluorimetric, UV melting profiles, circular dichroism and viscometric analysis. The binding of sanguinarine to A-form duplex RNA structures is characterised by the typical bathochromic and hypochromic effects in the absorption spectrum, increasing steady state fluorescence intensity, an increase in fluorescence quantum yield of sanguinarine, an increase in fluorescence polarization anisotropy, an increase of thermal transition temperature, an increase in the contour length of sonicated rod-like RNA structure and perturbation in circular dichroic spectrum. Scatchard analysis indicates that sanguinarine binds to each polymer in a non-cooperative manner. Comparative binding parameters determined from absorbance titration by Scatchard analysis, employing the excluded site model, indicate a higher binding affinity of sanguinarine to poly(rI).poly(rC) structure than to poly(rA).poly(rU) structure. On the basis of these observations, it is concluded that the alkaloid binds to both the RNA structures by a mechanism of intercalation.     

Carcinogenic purine N-oxide ester modifies covalently all common bases in polynucleotides

The carcinogen 1-methyl-3-hydroxyxanthine after esterification binds covalently to polynucleotides, RNA and DNA. All four ribopolynucleotides and poly(dT) are targets. Depending on reaction conditions, covalent binding is greatest to poly(A) followed by poly(U), poly(dT), poly(G), poly(C), RNA and DNA. Maximal covalent modification of DNA is one moiety per 360 nucleotides. All modified polynucleotides, RNA and DNA, except poly guanylic acid have been enzymatically digested and the major adducts characterized as nucleosides.     

Overexpression of poly(A) binding protein prevents maturation-specific deadenylation and translational inactivation in Xenopus oocytes.

The translational regulation of maternal mRNAs is the primary mechanism by which stage-specific programs of protein synthesis are executed during early development. Translation of a variety of maternal mRNAs requires either the maintenance or cytoplasmic elongation of a 3' poly(A) tail. Conversely, deadenylation results in translational inactivation. Although its precise function remains to be elucidated, the highly conserved poly(A) binding protein I (PABP) mediates poly(A)-dependent events in translation initiation and mRNA stability. Xenopus oocytes contain less than one PABP per poly(A) binding site suggesting that the translation of maternal mRNAs could be either limited by or independent of PABP. In this report, we have analyzed the effects of overexpressing PABP on the regulation of mRNAs during Xenopus oocyte maturation. Increased levels of PABP prevent the maturation-specific deadenylation and translational inactivation of maternal mRNAS that lack cytoplasmic polyadenylation elements. Overexpression of PABP does not interfere with maturation-specific polyadenylation, but reduces the recruitment of some mRNAs onto polysomes. Deletion of the C-terminal basic region and a single RNP motif from PABP significantly reduces both its binding to polyadenylated RNA in vivo and its ability to prevent deadenylation. In contrast to a yeast PABP-dependent poly(A) nuclease, PABP inhibits Xenopus oocyte deadenylase in vitro. These results indicate that maturation-specific deadenylation in Xenopus oocytes is facilitated by a low level of PABP consistent with a primary function for PABP to confer poly(A) stability.     

Binding of CC-1065 to poly- and oligonucleotides

The binding of the antitumor agent CC-1065 to a variety of poly- and oligonucleotides was studied by electronic absorption, CD, and resistance to removal by Sephadex column chromatography. Competitive binding experiments between CC-1065 and netropsin were carried out with calf-thymus DNA, poly(dI-dC) · poly(dI-dC), poly(dI) · poly(dC), poly(rA) · poly(dT), poly(dA- dC) · poly(dG-dT), and poly(dA) · 2poly(dT). CC-1065 binds to polynucleotides by three mechanisms. In the first, CC-1065 binds only weakly, as judged by the induction of zero or very weak CD spectra and low resistance to extraction of drug from the polynucleotide by Sephadex chromatography. In the second and third mechanisms, CC-1065 binds strongly, as judged by the induction of two distinct, intense CD spectra and high resistance to extraction of drug from the polynucleotide, by Sephadex chromatography in both cases. The species bound by the second mechanism converts to that bound by the third mechanism with varying kinetics, which depend both on the base-pair sequence and composition of the polynucleotide. Competitive binding experiments with netropsin show that CC-1065 binds strongly in the minor groove of DNA by the second and third mechanisms of binding. Netropsin can displace CC-1065 that is bound by the second mechanism but not that bound by the third mechanism. CC-1065 binds preferentially to B-form duplex DNA and weakly (by the first binding mechanism) or not at all to RNA, DNA, and RNA–DNA polynucleotides which adopt the A-form conformation or to single-strand DNA. This correlation of strong binding of CC-1065 to B-form duplex DNA is consistent with x-ray data, which suggest an anomalous structure for poly(dI) · poly(rC), as compared with poly(rI) · poly(dC) (A-form) and poly(dI) · poly(dC) (B-form). The binding data indicate that poly(rA) · poly(dU) takes the B-form secondary structure like poly(rA) · poly(dT). Triple-stranded poly(dA) · 2poly(dT) and poly(dA) · 2poly(dU), which are considered to adopt the A-form conformation, bind CC-1065 strongly. Netropsin, which also shows a binding preference for B-form polynucleotides, also binds to poly(dA) · 2poly(dT) and occupies the same binding site as CC-1065. These binding studies are consistent with results of x-ray studies, which suggest that A-form triplex DNA retains some structural features of B-form DNA that are not present in A-form duplex DNA; i.e., the axial rise per nucleotide and the base tilt. Triple-stranded poly(dA) · 2poly(rU) does not bind CC-1065 strongly but has nearly the same conformation as poly(dA) · 2poly(dT) based on x-ray analysis. This suggests that the 2′-OH group of the poly(rU) strands interferes with CC-1065 binding to this polynucleotide. The same type of interference may occur for other RNA and DNA–RNA polynucleotides that bind CC-1065 weakly.     

The preparation and characterization of locust vitellogenin messenger RNA and the synthesis of its complementary DNA.

Poly(A)+ (polyadenylated) RNA was isolated from vitellogenic female-locus fat-body by LiCl/urea extraction and poly(U)-Sepharose 4B affinity chromatography. Agarose-gel electrophoresis of this poly(A)+ RNA under denaturing conditions shows the presence of a high-molecular-weight species (greater than 31 S, 7100 nucleotides) as the major species, which is absent from the RNA prepared from male-locust fat-body. Inclusion of this poly(A)+ RNA in a mRNA-dependent reticulocyte-lysate system directs the synthesis of polypeptides that could be immunoprecipitated with monospecific antibodies against locust egg vitellin. DNA complementary (cDNA) to the poly(A)+ RNA was synthesized, and back-hybridization of the cDNA to its template reveals a major abundant species comprising about 45% of the total poly(A)+ RNA hybridizing with R0t 1/2 of 2 x 10(-2) mol . litre-1 . s. Abundant cDNA isolated from the total cDNA hybridizes to poly(A)+ RNA with a R0t 1/2 of 9 x 10(-3) mol . litre-1 . s. There are 9.1 x 10(3) copies of vitellogenin mRNA per cell of vitellogenic female-locust fat-body, comprising 55% of the poly(A)+ RNA and equivalent to 0.7% of total cellular RNA.     

Polyadenylated RNA isolated from the archaebacterium Halobacterium halobium.

Polyadenylated [poly(A)+] RNA has been isolated from the halophilic archaebacterium Halobacterium halobium by binding, at 4 degrees C, to oligo(dT)-cellulose. H. halobium contains approximately 12 times more poly(A) per unit of RNA than does the methanogenic archaebacterium Methanococcus vannielii. The 3' poly(A) tracts in poly(A)+ RNA molecules are approximately twice as long (average length of 20 nucleotides) in H. halobium as in M. vannielii. In both archaebacterial species, poly(A)+ RNAs are unstable.     

Addition of poly(adenylic acid) to RNA using polynucleotide phosphorylase: an improved method for electron microscopic visualization of RNA-DNA hybrids.

We have observed that the enzyme polynucleotide phosphorylas from M. luteus or from E. coli will polymerize adenosine (A) from adenosine diphosphate onto 3' ends of RNA molecules. For gene mapping, the poly(A)-tailed RNA is hybridized to its complementary sequence on a longer DNA strand. The position of the poly(A)tail, and thus the position of the 3' end of the RNA on the DNA strand, can then be observed by electron microscopy. Our preferred mapping technique involves the synthesis of a poly(A)-specific label by polymerization of a poly(dBrU) tail onto one or both ends of a linear duplex DNA of defined length (a restriction fragment) and hybridization of this label to the poly(A) tail. In test experiments with a plasmid containing a Drosophila DNA sequence coding for 5S rRNA genes, overall labeling efficiencies of 70--80% were achieved.     

Probing the binding of two sugar bearing anticancer agents aristololactam-β-(D)-glucoside and daunomycin to double stranded RNA polynucleotides: a combined spectroscopic and calorimetric study

The plant alkaloid aristololactam-β-d-glucoside and the anticancer chemotherapy drug daunomycin are two sugar bearing DNA binding antibiotics. The binding of these molecules to three double stranded ribonucleic acids, poly(A)·poly(U), poly(I)·poly(C) and poly(C)·poly(G), was studied using various biophysical techniques. Absorbance and fluorescence studies revealed that these molecules bound non-cooperatively to these ds RNAs with the binding affinities of the order 10(6) for daunomycin and 10(5) M(-1) for aristololactam-β-d-glucoside. Fluorescence quenching and viscosity studies gave evidence for intercalative binding. The binding enhanced the melting temperature of poly(A)·poly(U) and poly(I)·poly(C) and the binding affinity values evaluated from the melting data were in agreement with that obtained from other techniques. Circular dichroism results suggested minor conformational perturbations of the RNA structures. The binding was characterized by negative enthalpy and positive entropy changes and the affinity constants derived from calorimetry were in agreement with that obtained from spectroscopic data. Daunomycin bound all the three RNAs stronger than aristololactam-β-d-glucoside and the binding affinity varied as poly(A)·poly(U) > poly(I)·poly(C) > poly(C)·poly(G). The temperature dependence of the enthalpy changes yielded negative values of heat capacity changes for the complexation suggesting substantial hydrophobic contribution to the binding process. Furthermore, an enthalpy-entropy compensation behavior was also seen in all systems. These results provide new insights into binding of these small molecule drugs to double stranded RNA sequences.