Binding of the plant alkaloid aristololactam-β-d-glucoside and antitumor antibiotic daunomycin to single stranded polyribonucleotides

Background

Interaction of the plant alkaloid aristololactam-β-d-glucoside and the antitumor drug daunomycin with single stranded RNAs poly(G), poly(I), poly(C) and poly(U) has been investigated.

Methods

Biophysical techniques of absorption, fluorescence, competition dialysis, circular dichroism, and microcalorimetry have been used.

Results

Absorption and fluorescence studies have revealed noncooperative binding of ADG and DAN to the single stranded RNAs. The binding affinity of ADG varied as poly(G) > poly(I) > > poly(C) > poly(U). The affinity of DAN was one order higher than that of ADG and varied as poly(G) > poly(I) > poly(U) > poly(C). This binding preference was further confirmed by competition dialysis assay. The thermodynamics of the binding was characterised to be favourable entropy and enthalpic terms but their contributions were different for different systems. The major non-polyelectrolytic contribution to the binding revealed from salt dependent data appears to be arising mostly from stacking of DAN and ADG molecules with the bases leading to partial intercalation to single stranded RNA structures. Small negative heat capacity values have been observed in all the four cases.

Conclusions

This study presents the comparative structural and thermodynamic profiles of the binding of aristololactam-β-d-glucoside and daunomycin to single stranded polyribonucleotides.

General significance

These results suggest strong, specific but differential binding of these drug molecules to the single stranded RNAs and highlight the role of their structural differences in the interaction profile.     

Differences in physical and biological properties of 50S ribosomes and 23S RNAs derived from tight and loose couple 70S ribosomes

Tight couple (TC) 50S ribosomes on treatment with kethoxal lose their capacity to associate with 30S ribosomes whereas loose couple (LC) 50S ribosomes on such treatment fully retain their association capacity. The same is true for 23S RNAs isolated from treated 50S ribosomes or isolated 23S RNAs directly treated with kethoxal, so far as their capacity to associate with 16S RNA is concerned. At certain Mg++ concentrations TC 23S RNA is highly susceptible to the nucleolytic action of single-strand specific enzyme RNase I; LC 23S RNA is quite resistant. The Mg++-dependencies of the two species of 23S RNAs for association with 16S RNA are also quite different. The fluorescence enhancement of ethidium bromide due to binding to TC 23S RNA is slightly less than LC 23S RNA. The hyperchromicity of LC 23S RNA due to thermal denaturation is somewhat more than TC 23S RNA. LC 23S RNA has slightly more elliptic CD spectrum than TC 23S RNA. These results clearly show that 23S RNAs present in TC and LC 50S ribosomes are distinct from each other. It has been recently demonstrated in this laboratory that they can be interconverted by the agents involved in translocation and thus appear to be conformomers.     

Nuclease Stn α from <Emphasis Type="Italic">Streptomyces thermonitrificans</Emphasis>: Characterization of the Associated Adenylic Acid Preferential Ribonuclease Activity

Nuclease Stn α from Streptomyces thermonitrificans hydrolyses DNA and RNA at the rate of approximately 10:l. The optimum pH and temperature for RNA hydrolysis were 7.0 and 45°C. The RNase activity of nuclease Stn α had neither an obligate requirement of metal ions nor was it activated in the presence of metal ions. The enzyme was inhibited by Zn²⁺, Mg²⁺, Co²⁺, and Ca²⁺; inorganic phosphate; pyrophosphate; NaCl; KCl; and metal chelators. It was stable at high concentrations of urea but susceptible to low concentrations of Sodium dodecyl sulfate and guanidine hydrochloride. The rates by which nuclease Stn α hydrolysed polyribonucleotides occurs in the order of poly A >> RNA >> poly U > poly G > poly C. The enzyme cleaved RNA to 3′ mononucleotides with preferential liberation of 3′AMP, indicating it to be an adenylic acid preferential endonuclease.     

Base cleavage specificity of angiogenin with Saccharomyces cerevisiae and Escherichia coli 5S RNAs

The base cleavage specificity of angiogenin toward naturally occurring polyribonucleotides has been determined by using rapid RNA sequencing technology. With 5S RNAs from Saccharomyces cerevisiae and Escherichia coli, angiogenin cleaves phosphodiester bonds exclusively at cytidylic or uridylic residues, preferably when the pyrimidines are followed by adenine. However, not all of the existent pyrimidine bonds in the 5S RNAs are cleaved, likely owing to elements of structure in the substrate. Despite the high degree of sequence homology between angiogenin and ribonuclease A (RNase A), which includes all three catalytic as well as substrate binding residues, the cleavage patterns with natural RNAs are unique to each enzyme. Angiogenin significantly hydrolyzes certain bonds that are not appreciably attacked by RNase A and vice versa. The different cleavage specificities of angiogenin and RNase A may account for the fact that the former is angiogenic while the latter is not.     

Purification and properties of a ribonuclease from corn leaf tissues

An acid endoribonuclease isolated from corn leaf tissues was purified 530 times. Gel electrophoresis indicated that the enzyme was homogeneous. The enzyme showed an optimum pH at 5.5 and an apparent molecular weight of 32 000. Corn RNase attacks natural RNAs and synthetic polyribonucleotides and the relative rate of degradation was poly U > yeast RNA > E. coli tRNA > poly A ⪢ poly C. Zn²⁺, Mg²⁺, Mn²⁺ and EDTA inhibited the enzyme activity. No stimulation by K⁺ was observed. Cu²⁺ and heparin had no effect on the activity. The results suggest that the investigated RNase differs from other known corn ribonucleases.     

Identification and assignment of base pairs in three helical stems of Torulopsis utilis ribosomal 5S RNA and its RNase T1 and RNase T2 cleaved fragments via 500-MHz proton homonuclear overhauser enhancements

Imino proton resonances in the downfield region (10-14 ppm) of the 500-MHz 1H NMR spectrum of Torulopsis utilis 5S RNA are identified (A X U, G X C, or G X U) and assigned to base pairs in helices I, IV, and V via analysis of homonuclear Overhauser enhancements (NOE) from intact T. utilis 5S RNA, its RNase T1 and RNase T2 digested fragments, and a second yeast (Saccharomyces cerevisiae) 5S RNA whose nucleotide sequence differs at only six residues from that of T. utilis 5S RNA. The near-identical chemical shifts and NOE behavior of most of the common peaks from these four RNAs strongly suggest that helices I, IV, and V retain the same conformation after RNase digestion and that both T. utilis and S. cerevisiae 5S RNAs share a common secondary and tertiary structure. Of the four G X U base pairs identified in the intact 5S RNA, two are assigned to the terminal stem (helix I) and the other two to helices IV and V. Seven of the nine base pairs of the terminal stem have been assigned. Our experimental demonstration of a G X U base pair in helix V supports the 5S RNA secondary structural model of Luehrsen and Fox [Luehrsen, K. R., & Fox, G.E. (1981) Proc. Natl. Acad. Sci. U.S.A. 78, 2150-2154]. Finally, the base-pair proton peak assigned to the terminal G X U in helix V of the RNase T2 cleaved fragment is shifted downfield from that in the intact 5S RNA, suggesting that helices I and V may be coaxial in intact T. utilis 5S RNA.     

Nucleotide sequence of 5S ribosomal RNA from rainbow trout (Salmo gairdnerii) liver.

Staring from low molecular weight RNA obtained from rainbow trout (Salmo gairdnerii) liver, 5S ribosomal RNA (rRNA) was highly purified by successive chromatography on columns of DEAE-Sephadex A50 and Sephadex G100. Products of complete and partial digestions on this RNA with pancreatic ribonuclease (RNase A) [EC 3.1.4.22] and RNase T [EC 3.1.4.8] were isolated and sequenced by conventional and high-performance liquid chromatography (HPLC) procedures. The nucleotide sequence of this RNA thus established was compared with those of five other vertebrae 5S rRNAs, and the rates of base substitution per site per year were found to be nearly constant in these RNAs. The analyses of the partial digests of the trout 5S rRNA revealed several sites susceptible to RNase attack, which could be accounted for by the secondary structure model for eukaryotic 5S rRNAs proposed by Nishikawa and Takemura (1).     

The effect of tRNA binding on the structure of 5 S RNA in Escherichia coli. A chemical modification study

The structure of 5 S RNA within the 70 S ribosome from Escherichia coli was studied using the chemical reagent kethoxal (alpha-keto-beta-ethoxybutyraldehyde) to modify accessible guanosines. The modification pattern of 5 S RNA from free 70 S ribosomes was compared with that of poly(U) programmed ribosomes where tRNA had been bound to both the A- and P-sites. Binding to the ribosomal A-site was achieved enzymatically using the elongation factor Tu and GTP in the presence of deacylated tRNA which blocks the ribosomal P-site. Modified guanosines were identified after partial RNase T1 hydrolysis and separation of the hydrolysis products on sequencing gels. Binding of tRNA to the ribosome leads to a strong protection of 5 S RNA guanosine G-41 and to some degree G-44 from kethoxal modification. The limited RNase T1 hydrolysis pattern provides evidence for the existence of a 5 S RNA conformation different from the known 5 S RNA A- and B-forms which are characterized by their gel electrophoretic mobility. The importance of 5 S RNA for the binding of tRNA to the ribosome is discussed.     

Double-stranded RNA specific nuclease from germinating embryos ofPennisetum typhoides

A double-stranded RNA specific nuclease (ds RNase) has been purified from the pearl milletPennisetum typhoides. The purification involved S-30 preparation from the germinating embryos, DEAE-cellulose and DNA-cellulose chromatography. The partially pure enzyme preferentially solubilized the synthetic double-stranded polynucleotide [³H]poly(rA) · poly(rU); the degradation of [³H]poly(rC) was fourteen fold lower under the same assay conditions. Further more, the ds RNase activity was inhibited to an extent of 58% by ethidium bromide, which is known to intercalate with double-stranded RNAs. Active sulfhydryl groups were found to be necessary for the ds RNase activity since the enzyme action was inhibited by N-ethylmaleimide. Ethidium bromide and N-ethyl-maleimide did not significantly inhibit the ss RNase activity. In contrast, diethyl pyrocarbonate inhibited ss RNase activity completely and ds RNase by 58%. Heating the enzyme for 20 min at 50°C resulted in drastic loss of both enzyme activities. The ds RNase showed maximum activity in the pH range of 6.5 to 7.5. The enzyme actsin vitro onE. coli 30S precursor ribosomal RNA and the cleavage products migrated in the region of mature 23S and 16S rRNAs.     

Isolation and analysis of (Gp)nXp sequences of rat liver 5S RNA by means of restricted ribonuclease T2 hydrolysis

Essentual difficulties arise when base number in oligoguanylic blocks and location of these blocks along the polynucleotide chain need to be determined in the course of determination of the nucleotide sequences in ribonucleic acids. To overcome this difficulty it is suggested to take advantage of a recently discovered resistance of phosphodiester bond between kethoxalated G and its 3′-neighbour against T₂ RNase hydrolysis 1,2. The approach is illustrated by analysis of 5S RNA from rat liver. Sequences of general formula (Gp)_nXp were isolated from T₂ RNase hydrolysate of 5 S RNA rapidly and quantitatively. The information obtained greatly facilitates the whole procedure of sequencing. It is expected that the method proposed would be effective for analysis of 5 S and 4 S RNA and for highmolecular weight fragments of ribosomal and viral RNAs.     

Interaction of Escherichia coli DbpA with 23S rRNA in different functional states of the enzyme

DEx^D/_H proteins catalyze structural rearrangements in RNA by coupling ATP hydrolysis to the destabilization of RNA helices or RNP complexes. The Escherichia coli DEx^D/_H protein DbpA specifically recognizes a region within the catalytic core of 23S rRNA. To better characterize the interaction of DbpA with this region and to identify changes in the complex between different nucleotide-bound states of the enzyme, RNase T1, RNase T2, kethoxal and DMS footprinting of DbpA on a 172 nt fragment of 23S rRNA were performed. A number of protections identified in helices 90 and 92 were consistent with biochemical experiments measuring the RNA binding and ATPase activity of DbpA with truncated RNAs. When DbpA was bound with AMPPNP, but not ADP, several additional footprints were detected in helix 93 and the single-stranded region 5′ of helix 90, suggesting binding of the helicase domains of DbpA at these sites. These results propose that DbpA can act at multiple sites and hint at the targets of its biological activity on rRNA.     

RNase J is involved in the 5′-end maturation of 16S rRNA and 23S rRNA in Sinorhizobium meliloti

Sinorhizobium meliloti harbours genes encoding orthologs of ribonuclease (RNase) E and RNase J, the principle endoribonucleases in Escherichia coli and Bacillus subtilis, respectively. To analyse the role of RNase J in S. meliloti, RNA from a mutant with miniTn5-insertion in the RNase J-encoding gene was compared to the wild-type and a difference in the length of the 5.8S-like ribosomal RNA (rRNA) was observed. Complementation of the mutant, Northern blotting and primer extension revealed that RNase J is necessary for the 5′-end maturation of 16S rRNA and of the two 23S rRNA fragments, but not of 5S rRNA.     

The secondary structure of the protein L1 binding region of ribosomal 23S RNA. Homologies with putative secondary structures of the L11 mRNA and of a region of mitochondrial 16S rRNA.

An heterologous complex was formed between E. coli protein L1 and P. vulgaris 23S RNA. We determined the primary structure of the RNA region which remained associated with protein L1 after RNase digestion of this complex. We also identified the loci of this RNA region which are highly susceptible to T1, S1 and Naja oxiana nuclease digestions respectively. By comparison of these results with those previously obtained with the homologous regions of E. coli and B. stearothermophilus 23S RNAs, we postulate a general structure for the protein L1 binding region of bacterial 23S RNA. Both mouse and human mit 16S rRNAs and Xenopus laevis and Tetrahymena 28S rRNAs contain a sequence similar to the E. coli 23s RNS region preceding the L1 binding site. The region of mit 16S rRNA which follows this sequence has a potential secondary structure bearing common features with the L1-associated region of bacterial 23S rRNA. The 5'-end region of the L11 mRNA also has several sequence potential secondary structures displaying striking homologies with the protein L1 binding region of 23S rRNA and this probably explains how protein L1 functions as a translational repressor. One of the L11 mRNA putative structures bears the features common to both the L1-associated region of bacterial 23S rRNA and the corresponding region of mit 16S rRNA.     

Vesicular stomatitis virus mutant with altered polyadenylic acid polymerase activity in vitro.

In vitro RNA synthesis by purified virions of a stock of tsG16(I) was aberrant compared with that of wild-type (wt) vesicular stomatitis virus. RNA made in vitro by tsG16(I) contained a larger proportion of A residues in polyadenylic acid [poly(A)] tracts than did RNA synthesized by wt virus, tsG13(I), tsG21(II) or tsG41(IV). Experiments to determine whether the aberrant polyadenylation was correlated with the known thermolability of the tsG16(I) L protein were inconclusive. Total product RNA made by tsG16(I) was methylated to almost the same extent as wt RNA, contained the same major methylated 5' cap structure as wt RNA, and was translated as well in a reticulocyte cell-free system, yielding the same molecular weight proteins in similar ratios. Most polyadenylated [poly(A)+] RNA made by tsG16(I) was considerably larger than wt poly(A)+ RNA and richer in AMP:UMP residues; however, the protein-coding capacities of mutant and wt poly(A)+ RNAs were similar. This suggested that most mRNAs made in vitro by tsG16(I) might possess very long poly(A)+ tracts, and digestion of RNA by T1 RNase supported this. It appeared, therefore, that a virally coded component of vesicular stomatitis virus could affect polyadenylation. This could be the poly(A) polymerase itself, a protein involved in control of polyadenylation, or a protein which affects an event spatially and temporally connected with polyadenylation (such as initiation of the subsequent mRNA).     

Role of precursor sequences in the ordered maturation of E. coli 23S ribosomal RNA

The maturation of ribosomal RNAs (rRNAs) is an important but incompletely understood process required for rRNAs to become functional. In order to determine the enzymes responsible for initiating 3' end maturation of 23S rRNA in Escherichia coli, we analyzed a number of strains lacking different combinations of 3' to 5' exo-RNases. Through these analyses, we identified RNase PH as a key effector of 3' end maturation. Further analysis of the processing reaction revealed that the 23S rRNA precursor contains a CC dinucleotide sequence that prevents maturation from being performed by RNase T instead. Mutation of this dinucleotide resulted in a growth defect, suggesting a strategic significance for this RNase T stalling sequence to prevent premature processing by RNase T. To further explore the roles of RNase PH and RNase T in RNA processing, we identified a subset of transfer RNAs (tRNAs) that contain an RNase T stall sequence, and showed that RNase PH activity is particularly important to process these tRNAs. Overall, the results obtained point to a key role of RNase PH in 23S rRNA processing and to an interplay between this enzyme and RNase T in the processing of different species of RNA molecules in the cell.     

Cleavage of poly(A) tails on the 3'-end of RNA by ribonuclease E of Escherichia coli

RNase E initiates the decay of Escherichia coli RNAs by cutting them internally near their 5′-end and is a component of the RNA degradosome complex, which also contains the 3′-exonuclease PNPase. Recently, RNase E has been shown to be able to remove poly(A) tails by what has been described as an exonucleolytic process that can be blocked by the presence of a phosphate group on the 3′-end of the RNA. We show here, however, that poly(A) tail removal by RNase E is in fact an endonucleolytic process that is regulated by the phosphorylation status at the 5′- but not the 3′-end of RNA. The rate of poly(A) tail removal by RNase E was found to be 30-fold greater when the 5′-terminus of RNA substrates was converted from a triphosphate to monophosphate group. This finding prompted us to re-analyse the contributions of the ribonucleolytic activities within the degradosome to 3′ attack since previous studies had only used substrates that had a triphosphate group on their 5′-end. Our results indicate that RNase E associated with the degradosome may contribute to the removal of poly(A) tails from 5′-monophosphorylated RNAs, but this is only likely to be significant should their attack by PNPase be blocked.