Binding properties of Ru(II) polypyridyl complexes with poly(U)·poly(A)*poly(U) triplex: the ancillary ligand effect on third-strand stabilization

The binding properties of [RuL₂(mip)]²⁺ {where L is 1,10-phenanthroline (phen) or 4,7-dimethyl-1,10-phenanthrollne (4,7-dmp) and mip is 2′-(3″,4″-methylenedioxyphenyl)imidazo[4′,5′-f][1,10]phenanthroline} with regard to the triplex RNA poly(U)·poly(A)*poly(U) were investigated using various biophysical techniques and quantum chemistry calculations. In comparison with [Ru(4,7-dmp)₂(mip)]²⁺, remarkably higher binding affinity of [Ru(phen)₂(mip)]²⁺ for the triplex RNA poly(U)·poly(A)*poly(U) was achieved by changing the ancillary ligands. The stabilization of the Hoogsteen-base-paired third strand was improved by about 10.9 °C by [Ru(phen)₂(mip)]²⁺ against 6.6 °C by [Ru(4,7-dmp)₂(mip)]²⁺. To the best of our knowledge, [Ru(phen)₂(mip)]²⁺ is the first metal complex able to raise the third-strand stabilization of poly(U)·poly(A)*poly(U) from 37.5 to 48.4 °C. The results reveal that the ancillary ligands have an important effect on third-strand stabilization of the triplex RNA poly(U)·poly(A)*poly(U) when metal complexes contain the same intercalative ligands.     

Interaction between polyamines and nucleic acids or phospholipids

The binding of polyamines to DNA, RNA, and phospholipids has been studied by gel filtration and sucrose density gradient centrifugation. Spermine was found to bind more to a GC-rich DNA. Among RNAs containing double-stranded region [poly(AU), poly(GC), and ribosomal RNA], the binding of spermine was nearly equal. Among the single-stranded RNAs, the binding of spermine was in the order poly(U) > poly(C) > poly(A). An increase in K⁺ or Mg²⁺ concentration resulted in a great decrease in spermine binding to DNA and in a slight decrease in spermine binding to RNA. Therefore, in the presence of more than 2 mm Mg²⁺ and 100 mm K⁺, the binding of spermine to RNA was greater than that to DNA. No significant difference in spermine binding was observed between 16 S ribosomal RNA and 30 S ribosomal subunits, suggesting that ribosomal proteins did not affect significantly the binding of spermine to ribosomal RNA. The binding of spermine to microsomes was dependent on phospholipids. The binding strength was in the order phosphatidylinositol > phosphatidylethanolamine > phosphatidylcholine.     

Spatial distribution of mRNA during pre-fertilization ovule development in Capsella bursa-pastoris

Summary In situ hybridization of sections of the ovary and ovule of Capsella bursa-pastoris with ³H-polyuridylic acid [³H-poly(U)] showed the presence of polyadenylic acid-containing RNA [poly(A) + RNA] in the cells of the placenta and nucellus. During megasporogenesis there was a decrease in ³H-poly(U) binding activity of the nucellar cells concomitant with the appearance of poly(A) + RNA in the integuments. As the typical eight-nucleate embryo sac was formed, ³H-poly(U) binding was not apparent around the quartet of nuclei at the chalazal end, while it persisted at the micropylar end. Both the egg and synergids as well as the chalazal proliferating tissue showed high concentrations of poly(A) + RNA in their cytoplasm. The results suggest a role for transient localizations of poly(A) + RNA during female sporogenesis and gametogenesis in C. bursa-pastoris.     

Differential accumulation and localization of maternal poly(A)-containing RNA during early development of the ascidian,Styela

The regional distribution of poly(A)⁺ RNA was examined in sections of Styela oocytes and fertilized eggs by in situ hybridization with [³H]poly(U). The nucleus and cytoplasm of previtellogenic oocytes contain equivalent densities of [³H]poly(U) binding sites. The concentration of these sites is reduced in the cytoplasm, but not the nucleus, during vitellogenesis. Consequently, the germinal vesicle (GV) plasm of mature oocytes is characterized by an eightfold elevation in [³H]poly(U) binding activity relative to the surrounding cytoplasm. The distinctive cytoplasmic regions of the mature oocyte do not exhibit differential concentrations of [³H]poly(U) binding sites. Following fertilization which triggers GV breakdown, meiosis, and ooplasmic segregation, the high density of [³H]poly(U) binding sites characteristic of the GV plasm is conserved in the basophilic cytoplasm during its extensive migration and eventual accumulation in the animal hemisphere of the egg. The insensitivity of the [³H]poly(U) binding sites of the basophilic cytoplasm to actinomycin D suggests that they are of maternal origin. It is concluded that maternal poly(A)⁺ RNA is subject to differential accumulation in the GV plasm and its derivative ooplasm during the early development of Styela.     

A transient accumulation of poly(A)-containing RNA in the tapetum of Hyoscyamus niger during microsporogenesis

The distribution of poly(A)-containing RNA in the tapetal cells of Hyoscyamus niger during microsporogenesis was followed by in situ hybridization with [³H]poly(U) as a probe. Although no poly(A)-containing RNA accumulated in the premeiotic tapetum, [³H]poly(U) binding sites were detected in the tapetum as meiosis was completed in the microsporocytes. Accumulation of poly(A)-containing RNA in the tapetal cells reached a peak before the first haploid mitosis in the pollen grains. With the onset of tapetal senescence at the late uninucleate stage of the pollen grain, [³H]poly(U) binding sites gradually decreased and they completely disappeared in the tapetum at the binucleate pollen stage. The significance of the results is discussed, particularly with regard to the possible role of tapetum in the synthesis of informational macromolecules during microsporogenesis.     

Ddx42p--a human DEAD box protein with RNA chaperone activities

The human gene ddx42 encodes a human DEAD box protein highly homologous to the p68 subfamily of RNA helicases. In HeLa cells, two ddx42 poly(A)⁺ RNA species were detected both encoding the nuclear localized 938 amino acid Ddx42p polypeptide. Ddx42p has been heterologously expressed and its biochemical properties characterized. It is an RNA binding protein, and ATP and ADP modulate its RNA binding affinity. Ddx42p is an NTPase with a preference for ATP, the hydrolysis of which is enhanced by various RNA substrates. It acts as a non-processive RNA helicase. Interestingly, RNA unwinding by Ddx42p is promoted in the presence of a single-strand (ss) binding protein (T4gp32). Ddx42p, particularly in the ADP-bound form (the state after ATP hydrolysis), also mediates efficient annealing of complementary RNA strands thereby displacing the ss binding protein. Ddx42p therefore represents the first example of a human DEAD box protein possessing RNA helicase, protein displacement and RNA annealing activities. The adenosine nucleotide cofactor bound to Ddx42p apparently acts as a switch that controls the two opposing activities: ATP triggers RNA strand separation, whereas ADP triggers annealing of complementary RNA strands.     

Poly(U) binding to ascites cells of the 13762A rat mammary adenocarcinoma: Evidence for a protein receptor on the cell surface

Ascites cells of the 13762 rat mammary adenocarcinoma bind poly(U) in a reaction that is complete within 5 min at 0°C. Poly(U) binding is saturable; the capacity of these cells is 5×10⁷ UMP residues/cell (approx. 2×10⁵ chains/cell). Most [³H]poly(U) bound in the rapid reaction can be recovered in an undergraded state. However, it is rapidly degraded by low concentrations of exogenous pancreatic ribonuclease. The magnitude of binding is independent of temperature and ionic conditions, and is unaffected by metabolic inhibitors or concanavalin A (ConA). Radioactivity presented as [³H]poly(U) tends to co-fractionate with 5′-nucleotidase after homogenization of cells in the media of low ionic strength, but is efficiently released from cells exposed to protein denaturants that effectively fix cellular RNA in situ. Cells pretreated with proteolytic enzymes have sharply reduced capacities to bind poly(U). Autoradiography of cells bearing [³H]poly(U) demonstrates a uniform distribution of radioactivity through the cell population and is consistent with binding to the plasma membrane. These and other results imply that binding of poly(U) to 13762 ascites cells is mediated by protein receptors on the cell surface.     

Binding affinity and in vitro cytotoxicity of harmaline targeting different motifs of nucleic acids: An ultimate drug designing approach

The work focuses towards interaction of harmaline, with nucleic acids of different motifs by multispectroscopic and calorimetric techniques. Findings of this study suggest that binding constant varied in the order single‐stranded (ss) poly(A) > double‐stranded calf thymus (CT) DNA > double‐stranded poly(G)·poly(C) > clover leaf tRNA^Phe. Prominent structural changes of ss poly(A), CT DNA, and poly(G)· poly(C) with concomitant induction of optical activity in the bound achiral alkaloid molecule was observed, while with tRNA^Phe, very weak induced circular dichroism perturbation was seen. The interaction was predominantly exothermic, enthalpy driven, and entropy favored with CT DNA and poly(G)·poly(C), while it was entropy driven with poly(A) and tRNA^Phe. Intercalated state of harmaline inside poly(A), CT DNA, and poly(G)·poly(C) was shown by viscometry, ferrocyanide quenching, and molecular docking. All these findings unequivocally pointed out preference of harmaline towards ss poly(A) inducing self‐structure formation. Furthermore, harmaline administration caused a significant decrease in proliferation of HeLa and HepG₂ cells with GI₅₀ of 28μM and 11.2μM, respectively. Nucleic acid fragmentation, cellular ultramorphological changes, decreased mitochondrial membrane potential, upregulation of p53 and caspase 3, generation of reactive oxygen species, and a significant increase in the G₂/M population made HepG₂ more prone to apoptosis than are HeLa cells.     

Influence of monovalent cations on magnesium binding to poly-RNA by solution titration calorimetry: an analysis of the salt dependence of binding enthalpies and entropies

 The salt dependence of the binding constant (K) and enthalpic (ΔH) and entropic (ΔS) components for magnesium binding to poly-RNA was determined as a function of the concentration and identity of monovalent counter ions (M⁺). Both ΔH and ΔS were found to vary linearly with ln [M⁺]. A theoretical analysis of the experimental data revealed that the temperature dependence of the product of the density of bound counter ions and the electrostatic interaction parameter, δ(m′ψ)/δT, is non-negligible, although it has previously been ignored. The sign of δ(m′ψ)/δT was negative for poly(A) and positive for poly(U), indicating that the charge density of poly(A) decreased with temperature, while that of poly(U) increased. These results are related to the distinct solution structures of the RNA homopolymers. Considerable support was lent to this calorimetric approach by the excellent agreement obtained in a test comparison between experimental and calculated parameters. From the intercept of energy term versus ln [M⁺] plots, the non-electrostatic contributions, ΔH° and ΔS°, were determined. For each polynucleotide, the similarity in ΔG° over the series of monovalent ions used in each study suggests a compensatory relationship between ΔH° and ΔS°, each of which shows significant variation. The non-electrostatic contribution to binding of divalent magnesium is generally entropically favorable and enthalpically unfavorable for both poly(A) and poly(U). Received: 2 August 1995 / Accepted: 12 October 1995     

Macrocyclic zinc(II) complexes for selective recognition of nucleobases in single- and double-stranded polynucleotides

 As an extension of our earlier discoveries that Zn^II-cyclen complex (1) (cyclen=1,4,7,10-tetraazacyclododecane) and Zn^II-acridine-pendant cyclen complex Zn^II-N-(9-acridin)ylmethyl-cyclen (3) are the first compounds to selectively recognize thymidine and uridine nucleosides in aqueous solution at physiological pH, the interaction of these and a relevant complex, bis(Zn^II-cyclen) (7), has been investigated with a series of polynucleotides, single-stranded poly(U) and poly(G), and double-stranded poly(A)·poly(U), poly(dA)·poly(dT) and poly(dG)·poly(dC). These Zn^II-cyclen complexes interact with the imide-containing nucleobases in the single-stranded poly(U), unperturbed by the presence of the anionic phosphodiester backbone. The affinity constant of 1 for each N(3)-deprotonated uracil base in poly(U) is determined to be log K= 5.1 by a kinetic measurement, which is almost the same as log K=5.2 for the interaction of 1 with uridine. Thus, they disrupt the A-U (or A-T) hydrogen bonds to unzip the duplex of poly(A)·poly(U) or poly(dA)·poly(dT), as demonstrated by lowering of the melting temperatures (T _m) of poly(A)·poly(U) and poly(dA)·poly(dT) in 5 mM Tris-HCl buffer (pH 7.6, 10 mM NaCl) with increase in their concentrations. The order of the denaturing efficiency is well correlated with that of the 1 : 1 affinity constants for each complex with uracil or thymine;7>3>1. The comparison of circular dichroism (CD) spectra for poly(A)·poly(U), poly(A), and poly(U) in the presence of 3 has revealed a structural change from poly(A)·poly(U) to two single strands, poly(A) and poly(U), caused by 3 binding exclusively to uracils in poly(U). On the other hand, the acridine-pendant cyclen complex 3, which earlier was found to associate with guanine by the Zn^II coordinating with guanine N(7), in addition to the π-π stacking, interacts with guanine in the double helix of poly(dG)·poly(dC) from outside and stabilized the double-stranded structure, as indicated by higher T _m. Received: 31 December 1997 / Accepted: 23 February 1998     

Targeting different RNA motifs by beta carboline alkaloid,harmalol: a comparative photophysical,calorimetric, and molecular docking approach

RNA has attracted recent attention for its key role in gene expression and targeting by small molecules for therapeutic intervention. This work focuses towards understanding interaction of harmalol, a DNA intercalator, with RNAs of different motifs viz. single-stranded A-form poly(A), double-stranded A-form of poly(C)·poly(G), and clover leaf tRNA^phe by different spectroscopic, calorimetric, and molecular modeling techniques. Results of this study converge to suggest that (i) binding constant varied in the order poly(C)·poly(G)?>?tRNA^phe > poly(A), (ii) non-cooperative binding of harmalol to poly(C)·poly(G) and poly(A) and cooperative binding with tRNA^phe, (iii) significant structural changes of poly(C)·poly(G) and tRNA^phe with concomitant induction of optical activity in the bound achiral alkaloid molecules, while with poly(A) no induced Circular dichroism (CD) perturbation was observed, (iv) the binding was predominantly exothermic, enthalpy-driven, entropy-favored with poly(C)·poly(G), while it was entropy driven with tRNA^phe and poly(A), (v) a hydrophobic contribution and comparatively large role of non polyelectrolytic forces to Gibbs energy changes with poly(C)·poly(G) and tRNA^phe and (vi) intercalated state of harmalol inside poly(C)·poly(G) structure as revealed from molecular docking was supported by the viscometric and ferrocyanide quenching data. All these findings unequivocally pointed out that harmalol prefers binding with poly(C)·poly(G), compared to tRNA^phe and poly(A); this results serve as data for the development of RNA-based antiviral drugs.     

Small molecule–RNA interaction: Spectroscopic and calorimetric studies on the binding by the cytotoxic protoberberine alkaloid coralyne to single stranded polyribonucleotides

Background

RNA has attracted recent attention for its key role in gene expression and hence targeting by small molecules for therapeutic intervention. This study is aimed to elucidate the specificity of the alkaloid coralyne to poly(G), poly(C), poly(I) and poly(U) in the light of its ability in inducing self-structure in poly(A).

Methods

Multifaceted experimental techniques like competition dialysis, absorption, fluorescence, circular dichroism and calorimetry were employed. Salt dependence and temperature dependence of the binding was also elucidated.

Results

Results of competition dialysis, absorption and fluorescence studies revealed that coralyne binds strongly to the polypurines, poly(G) and poly(I) compared to the polypyrimidines, poly(U) and poly(C). Partial intercalative binding due to the stacking of the molecules between the bases was envisaged. The binding was predominantly enthalpy driven with favourable entropy term with a large favourable non-electrostatic contribution revealed from salt dependent data and the dissection of the free energy. The heat capacity change of − 125 and − 119 cal/mol K^− 1 respectively for poly(G) and poly(I) and the partial enthalpy–entropy compensation phenomenon observed confirmed the involvement of multiple weak noncovalent interactions. Circular dichroism studies provided evidence for significant perturbation of the conformation of the RNAs, but no self-structure induction was evident in any of the polymers under the condition of the study.

Conclusions

This study presents a complete structural and thermodynamic profile of coralyne interaction to four single stranded RNA polymers.

General significance

The study for the first time elucidates the base specificity of coralyne–RNA complexation at the single stranded level.     

Kinetic study of protein unfolding and refolding using urea gradient electrophoresis

When total cytoplasmic RNA from mouse Friend cells is fractionated using oligo(dT)-cellulose or poly(U)-Sepharose chromatography, approximately 20% of the messenger RNA activity (as measured in the reticulocyte lysate cell-free system) remains in the unbound fraction, even though this contains < 0.5% of the poly(A) (as measured by titration with poly(U)). This RNA, operationally defined as poly(A)^?, is found almost entirely in polysome structures in vivo. Its major translation products, as shown by one-dimensional sodium dodecyl sulphate-containing gels, are the histones and actin. Two-dimensional gels (isoelectric focusing: sodium dodecyl sulphate/gel electrophoresis) show that, with the exception of the mRNAs coding for histones, poly(A)^? mRNA encodes similar proteins to poly(A)⁺ mRNA, though in very different abundances. This is directly confirmed by the arrest of the translation of the abundant poly(A)^? mRNAs after hybridization with a complementary DNA transcribed from poly(A)⁺ RNA.RNA sequences which are rare in the poly(A)⁺ RNA are also found in poly(A)^? RNA, as shown by hybridizing a cDNA transcribed from poly(A)⁺ RNA to total and poly(A)^? polysomal RNA. That this does not simply represent a flow-through of poly(A)⁺ RNA is indicated by (i) the lack of poly(A) by hybridizing to poly(U) in this fraction, (ii) the fact that further passage through poly(U)-Sepharose does not remove the hybridizing sequences, (iii) the very different quantitative distribution of proteins encoded by poly(A)⁺ and poly(A)^? RNAs. We also think that it does not result from removal of poly(A) from polyadenylated RNAs during extraction because RNAs prepared using the minimum of manipulations give similar results. The distribution of both total mRNA and α and β globin mRNAs between poly(A)⁺ and poly(A)^? RNA does not change significantly during the dimethyl sulphoxide-induced differentiation of Friend cells.     

The binding of Mg++ ions to polyadenylate, polyuridylate, and their complexes

The binding of Mg ⁺⁺ to polyadenylate (poly A), Polyuridylate(poly U), and their complexes, poly (A + U) and poly (A + 2U), was studied by means of a technique in which the dye eriochrome black T is used to measure the concentration of free Mg^?. The apparent binding constant K_X = [MgN]/[Mg⁺⁺][N], N = site for Mg⁺⁺ binding (the phosphate group of the nucleotide), was found to decrease rapidly as the extent of binding increased and, at low extents of binding, as the concentration of Na^? increased in poly A, poly (A + U), and poly (A + 2U), and somewhat less so in poly U. K_x is generally in the range 10⁴ > K_X > 10². The cause of these dependences is apparently, primarily, the displacement of Na⁺ by Mg⁺⁺ in poly U and poly (A + U) on the basis of the similarity of extents of displacement measured in this work and those measured potentiometrically. was calculated and was found to approach zero as the concentration of Na⁺ increased. In poly U, poly (A + U), and poly (A + 2U) at low ΔH′ v.H. > 0, about + 2 kcal/“mole.” In poly A, also at low salt, ΔH′ v.H. ≈ ?4 kcal/“mol” for the initial binding of Mg⁺⁺, and increases to +2 kcal/“mol” at saturation. This enthalpic variation probably accounts for the anticooperativity in the binding of Mg⁺⁺ not ascribable to the displacement of Na⁺⁺.     

Subunit interactions of rabbit muscle aldolase. Conformational change of aldolase in magnesium chloride and its relationship to the dissociation of subunits.

The effect of Escherichia coli ribosomal protein S1 on translation has been studied in S1-depleted systems programmed with poly(U), poly(A) and MS2 RNA³. The translation of the phage RNA depends strictly on the presence of S1. Optimum poly(U)-directed polyphenylalanine synthesis and poly(A)-programmed polylysine synthesis also require S1. Excess S1 relative to ribosomes and messenger RNA results in inhibition of translation of MS2 RNA and poly(U), but not of poly (A). In the case of phage RNA translation, this inhibition can be counteracted by increasing the amount of messenger RNA. Three other 30 S ribosomal proteins (S3, S14 and S21) are also shown to inhibit MS2 RNA translation. The effects of S1 on poly(U) translation were studied in detail and shown to be very complex. The concentration of Mg²⁺ in the assay mixtures and the ratio of S1 relative to ribosomes and poly(U) are crucial factors determining the response of this translational system towards the addition of S1. The results of this study are discussed in relation to recent developments concerning the function of this protein.     

A template independent, rifampicin sensitive poly (A).poly (U) synthesizing activity present in Bacillus subtilis.

A template independent poly (A)·poly (U) synthesizing activity has been isolated from $\text{Bacillus subtilis}$. This activity is eluted from a DNA-cellulose column along with DNA-dependent RNA polymerase. The column fractions which exhibit this activity contain RNA polymerase holoenzyme plus a polypeptide which is slightly larger than sigma factor; pure RNA polymerase holoenzyme did not synthesize poly (A)·poly (U). The activity was dependent on the presence of ATP, UTP, and Mn⁺⁺ (Mg⁺⁺ could not substitute), and was inhibited by rifampicin, streptolydigin, and Cibacron Blue. The incorporation of nucleotides was not linear with time, but appeared after a lag period. The results suggest that a modified form of DNA-dependent RNA polymerase analogous to $\text{Escherichia coli}$ holoenzyme II is catalyzing the synthesis of poly (A)·poly (U).     

Molecular dynamics simulation studies of induced fit and conformational capture in U1A–RNA binding: Do molecular substates code for specificity?

Molecular dynamics (MD) simulations on stem loop 2 of U1 small nuclear RNA and a construct of the U1A protein were carried out to obtain predictions of the structures for the unbound forms in solution and to elucidate dynamical aspects of induced fit upon binding. A crystal structure of the complex between the U1A protein and stem loop 2 RNA and an NMR structure for the uncomplexed form of the U1A protein are available from Oubridge et al. (Nature, 1994, Vol. 372, pp. 432-438) and Avis et al. (Journal of Molecular Biology, 1996, Vol. 257, pp. 398-411), respectively. As a consequence, U1A-RNA binding is a particularly attractive case for investigations of induced fit in protein-nucleic acid complexation. When combined with the available structural data, the results from simulations indicate that structural adaptation of U1A protein and RNA define distinct mechanisms for induced fit. For the protein, the calculations indicate that induced fit upon binding involves a non-native thermodynamic substate in which the structure is preorganized for binding. In contrast, induced fit of the RNA involves a distortion of the native structure in solution to an unstable form. However, the RNA solution structures predicted from simulation show evidence that structures in which groups of bases are favorably oriented for binding the U1A protein are thermally accessible. These results, which quantify with computational modeling recent proposals on induced fit and conformational capture by Leuillot and Varani (Biochemistry, 2001, Vol. 40, pp. 7947-7956) and by Williamson (Nature Structural Biology, 2000, Vol. 7, pp. 834-837) suggest an important role for intrinsic molecular architecture and substates other than the native form in the specificity of protein-RNA interactions.     

Dependence of 4'-(hydroxymethyl)-4,5',8-trimethylpsoralen photoaddition on the conformation of ribonucleic acid

The photoaddition of 4'-(hydroxymethyl)-4,5',8-trimethylpsoralen (HMT) to different conformational states of RNA was studied. Poly(U), poly(A,U) (random copolymer), poly(A-U) (alternating copolymer), poly(A) . poly(U) (double stranded), and poly(U) . poly(A) . poly(U) (triple stranded) were reacted with HMT at different temperatures and salt concentrations. The conformation of the polymers was monitored by UV absorption and circular dichroism. It was found that the rate of HMT photoaddition changed dramatically at structural transitions in the RNA. The alternating copolymer poly(A-U) was found to have the highest rate of addition. Low salt and temperature produced maximal incorporation.