Comparative study on the biological properties of 2',5'-oligoadenylate derivatives with purified human RNase L expressed in E. coli

An endoribonuclease, RNase L, which is activated in the presence of 2',5'-linked oligoadenylates, p(1-3)A(2'p5'A)(>2), is the terminal factor of the anti-viral action of interferon. Activation of RNase L results in inhibition of viral proliferation along with induction of apoptosis. Attempts to acquire more effective activators, 2-5A derivatives, have been made for the development of antiviral or anticancer agents. However, the ability of 2-5A derivatives to activate RNase L could not simply be compared due to the diversity of the assay methods used. We have now developed a facile method for assaying the activity of RNase L involving the use of non-fusion RNase L expressed in Escherichia coli and yeast 5S ribosomal RNA as a substrate. Using this method, several 2-5A derivative species have been revaluated. The results suggest that 2-5A molecules modified at the 8-position of the third (from the 5' terminus) adenine ring cause effective dimerization of RNase L and thus increase the ability of RNase L activation.     

Dynamics of ribonuclease A and ribonuclease S: computational and experimental studies.

RNase S is a complex consisting of two proteolytic fragments of RNase A: the S peptide (residues 1-20) and S protein (residues 21-124). RNase S and RNase A have very similar X-ray structures and enzymatic activities. Previous experiments have shown increased rates of hydrogen exchange and greater sensitivity to tryptic cleavage for RNase S relative to RNase A. It has therefore been asserted that the RNase S complex is considerably more dynamically flexible than RNase A. In the present study we examine the differences in the dynamics of RNase S and RNase A computationally, by MD simulations, and experimentally, using trypsin cleavage as a probe of dynamics. The fluctuations around the average solution structure during the simulation were analyzed by measuring the RMS deviation in coordinates. No significant differences between RNase S and RNase A dynamics were observed in the simulations. We were able to account for the apparent discrepancy between simulation and experiment by a simple model. According to this model, the experimentally observed differences in dynamics can be quantitatively explained by the small amounts of free S peptide and S protein that are present in equilibrium with the RNase S complex. Thus, folded RNase A and the RNase S complex have identical dynamic behavior, despite the presence of a break in polypeptide chain between residues 20 and 21 in the latter molecule. This is in contrast to what has been widely believed for over 30 years about this important fragment complementation system.     

The role of the S1 domain in exoribonucleolytic activity: substrate specificity and multimerization

RNase II is a 3'-5' exoribonuclease that processively hydrolyzes single-stranded RNA generating 5' mononucleotides. This enzyme contains a catalytic core that is surrounded by three RNA-binding domains. At its C terminus, there is a typical S1 domain that has been shown to be critical for RNA binding. The S1 domain is also present in the other major 3'-5' exoribonucleases from Escherichia coli: RNase R and polynucleotide phosphorylase (PNPase). In this report, we examined the involvement of the S1 domain in the different abilities of these three enzymes to overcome RNA secondary structures during degradation. Hybrid proteins were constructed by replacing the S1 domain of RNase II for the S1 from RNase R and PNPase, and their exonucleolytic activity and RNA-binding ability were examined. The results revealed that both the S1 domains of RNase R and PNPase are able to partially reverse the drop of RNA-binding ability and exonucleolytic activity resulting from removal of the S1 domain of RNase II. Moreover, the S1 domains investigated are not equivalent. Furthermore, we demonstrate that S1 is neither responsible for the ability to overcome secondary structures during RNA degradation, nor is it related to the size of the final product generated by each enzyme. In addition, we show that the S1 domain from PNPase is able to induce the trimerization of the RNaseII-PNP hybrid protein, indicating that this domain can have a role in the biogenesis of multimers.     

Identification of the nucleotide sequences involved in the interaction between Escherichia coli 5 RNA and specific 50 S subunit proteins

Pancreatic RNase partial digests of ³²P-labelled 5 S RNA-protein complexes have been fractionated by electrophoresis on polyacrylamide gels. Specific fragments of the 5 S RNA molecule have been recovered from electrophoresis bands containing polynucleotide-protein complexes. These digestion-resistant complexes are only found if RNase treatment is carried out in the presence of at least one of the two 50 S subunit proteins L18 and L25, which are able to bind to 5 S RNA individually and specifically. The sequences of the isolated fragments have been determined. From the results, it can be concluded that sequence 69 to 120 and, possibly, sequence 1 to 11, are involved in the 5 S RNA-protein interactions which are responsible for the insertion of 5 S RNA in the 50 S subunit structure. Sequence 12 to 68, on the other hand, has no strong interactions with proteins L18 and L25. Each protein certainly binds to several nucleotide residues, which are not contiguous in the primary structure. In particular, good experimental evidence has been obtained in favour of the binding of protein L25 to two distant regions of the 5 S RNA molecule, which must have a bihelical secondary structure. The importance of the 5 S RNA conformation for its proper insertion in the 50 S subunit is thus confirmed.     

Structural analyses of E. coli 5S RNA fragments, their associates and complexes with proteins L18 and L25.

The structure of Escherichia coli 5S RNA fragments 1-41 and 42-120 has been studied by the read-off gel sequencing technique using S1 nuclease and cobra venom RNase as probes. Comparison of the digestion patterns with those of reassociated and intact 5S RNA suggests that the structure of both fragments is very similar to that of the corresponding regions in the intact molecule. Six different fragments obtained by partial digestion with T1 RNase and S1 nuclease have been used for reconstitution of 5S RNA, its certain structural regions and complexes with ribosomal proteins L18 and L25 recognizes the double-helix consisting of nucleotides 79-97 (i.e. prokaryotic stem), whereas a loop-region around position 40 (possible positions 39-47) is involved in the interaction with protein L18.     

金鱼草自交不亲和位点位于着丝粒的周边区

在蔷薇科,茄科和玄参科配子体自交不亲和中,编码花柱的SRNase控制花柱的自交不亲和性,在前两科植物中,自交不亲和（S）位点定位于着丝粒的附近,但在玄参科植物金鱼草（Antirrhinum)中自交不亲和位点至今未知,为了确定它在染色体上的位置和基因组结构,以基因型S2S5金鱼草根尖为材料,进行染色体的制备观察,利用地高辛标记的S2RNase和含有其全长的BAC克隆（S2BAC）为探针进行荧光染色体原位杂交（FISH）,发现S2RNase杂交信号位于染色体的着丝粒附近,而S2BAC的杂交信号位于每条染色体的着丝粒的周边区,呈对称的4个,表明金鱼草S位点位于着丝粒的周边区,对S2BAC预测基因的分析表明,发现一个金鱼草新的反转座子（RIS1）。结果显示,金鱼草S位点位于染色体着丝粒的周边区,富含转座子和反转座子,和其他两类配子体自交不亲和的位置类似,预示它们的共同起源和具有抑制重组的功能。     

Differential association of protein subunits with the human RNase MRP and RNase P complexes

RNase MRP is a eukaryotic endoribonuclease involved in nucleolar and mitochondrial RNA processing events. RNase MRP is a ribonucleoprotein particle, which is structurally related to RNase P, an endoribonuclease involved in pre-tRNA processing. Most of the protein components of RNase MRP have been reported to be associated with RNase P as well. In this study we determined the association of these protein subunits with the human RNase MRP and RNase P particles by glycerol gradient sedimentation and coimmunoprecipitation. In agreement with previous studies, RNase MRP sedimented at 12S and 60-80S. In contrast, only a single major peak was observed for RNase P at 12S. The analysis of individual protein subunits revealed that hPop4 (also known as Rpp29), Rpp21, Rpp20, and Rpp25 only sedimented in 12S fractions, whereas hPop1, Rpp40, Rpp38, and Rpp30 were also found in 60-80S fractions. In agreement with their cosedimentation with RNase P RNA in the 12S peak, coimmunoprecipitation with VSV-epitope-tagged protein subunits revealed that hPop4, Rpp21, and in addition Rpp14 preferentially associate with RNase P. These data show that hPop4, Rpp21, and Rpp14 may not be associated with RNase MRP. Furthermore, Rpp20 and Rpp25 appear to be associated with only a subset of RNase MRP particles, in contrast to hPop1, Rpp40, Rpp38, and Rpp30 (and possibly also hPop5), which are probably associated with all RNase MRP complexes. Our data are consistent with a transient association of Rpp20 and Rpp25 with RNase MRP, which may be inversely correlated to its involvement in pre-rRNA processing.     

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.     

Characterization of the RNase P RNA of Sulfolobus acidocaldarius.

RNase P is the ribonucleoprotein enzyme that cleaves precursor sequences from the 5' ends of pre-tRNAs. In Bacteria, the RNA subunit is the catalytic moiety. Eucaryal and archaeal RNase P activities copurify with RNAs, which have not been shown to be catalytic. We report here the analysis of the RNase P RNA from the thermoacidophilic archaeon Sulfolobus acidocaldarius. The holoenzyme was highly purified, and extracted RNA was used to identify the RNase P RNA gene. The nucleotide sequence of the gene was determined, and a secondary structure is proposed. The RNA was not observed to be catalytic by itself, but it nevertheless is similar in sequence and structure to bacterial RNase P RNA. The marked similarity of the RNase P RNA from S. acidocaldarius and that from Haloferax volcanii, the other known archael RNase P RNA, supports the coherence of Archaea as a phylogenetic domain.     

Mini-III, an unusual member of the RNase III family of enzymes, catalyses 23S ribosomal RNA maturation in B. subtilis

The late steps of both 16S and 5S ribosomal RNA maturation in the Gram-positive bacterium Bacillus subtilis have been shown to be catalysed by ribonucleases that are not present in the Gram-negative paradigm, Escherichia coli. Here we present evidence that final maturation of the 5' and 3' extremities of B. subtilis 23S rRNA is also performed by an enzyme that is absent from the Proteobacteria. Mini-III contains an RNase III-like catalytic domain, but curiously lacks the double-stranded RNA binding domain typical of RNase III itself, Dicer, Drosha and other well-known members of this family of enzymes. Cells lacking Mini-III accumulate precursors and alternatively matured forms of 23S rRNA. We show that Mini-III functions much more efficiently on precursor 50S ribosomal subunits than naked pre-23S rRNA in vitro, suggesting that maturation occurs primarily on assembled subunits in vivo. Lastly, we provide a model for how Mini-III recognizes and cleaves double-stranded RNA, despite lacking three of the four RNA binding motifs of RNase III.     

Oligonucleotide sequences of pancreatic and T1 ribonuclease digests of 5S ribosomal RNA from mouse cells.

Oligonucleotides produced by complete pancreatic and T1 RNase digestion of 5S ribosomal RNA from a mouse hepatoma, MH 134, have been separated with two-dimensional electrophoresis and their nucleotide sequences determined. Except for the presence of a 5'-terminal diphosphate, these nucleotide sequences were identical with those of KB cells, confirming the identity of the primary structure of 5S RNA between these animals. Both oligonucleotide patterns produced with these enzymes from 5S RNA of the liver were also identical with those of the hepatoma. All these agree with the strong conservation of 5S RNA genes in animal species. However, when 5S ribosomal RNA was extracted from ribosomes which were prepared from microsomal pellet, pancreatic RNase digest contained two trinucleotides (A-G-Cp and G-A-Cp) that were not found in 5S RNA prepared with a one-step procedure. It was concluded that different isolation procedure might indeed cause artifactual fragments on enzymatic digestion due to internal nicks produced during isolation. The significance of 5'-terminal diphosphate in relation to the biosynthesis of 5S ribosomal RNA is also discussed.     

Effect of ribonuclease on the physico-chemical properties of estrogen receptor

Estrogen receptors (ER) from rat and rabbit uterine cytosol were examined for their sensitivity to ribonuclease (RNase). After RNase treatment, a major part of rabbit uterine ER was converted from the 7S to 3-4S form, and its binding to DNA-cellulose was increased by 40%. Similar treatment on rat uterine ER showed a shift from 7S to 4.5S, and the DNA-cellulose binding was stimulated by 20%. Measurement of endogenous RNase levels showed that lower RNase concentration in rabbit uterine cytosol coincided with larger stimulation of DNA-cellulose binding by exogenous RNase. These results indicate that a major part of 7S ER is susceptible to RNase, and cleavage of bound RNA seems to uncover additional binding sites for DNA. In contrast to the general thinking that 4S to 5S transformation is essential for nuclear binding, we have observed that RNase-treated rat uterine ER did not undergo such a transformation by warming at 25 degrees C, while DNA-cellulose binding of the receptors increased. Thus, temperature activation could occur independent of 4S to 5S transformation.     

NMR evidence for dynamic secondary structure in helices II and III of the RNA of Escherichia coli

A new ribonuclease A (RNase A) resistant fragment of the 5S ribonucleic acid (RNA) from Escherichia coli has been isolated and characterized. This fragment comprises helix III and most of helix II of the parent molecule, a part of the 5S RNA molecule for which several energetically equivalent secondary structures have been proposed [De Wachter, R., Chen, M.-W., & Vandenberghe, A. (1984) Eur. J. Biochem. 143, 175-182]. The imino proton spectrum of this fragment has been studied by nuclear magnetic resonance methods at 500 MHz. The data obtained are readily rationalized in terms of one of the structures proposed for this region of 5S RNA. They also suggest that upon heating, this structure is replaced by a second, different one, consistent with the view that the helix II-helix III region of 5S RNA is able to switch between alternative structures. Among the products of the nucleolytic digestion of 5S RNA is a species whose sequence indicates that RNase A can ligate RNA as well as hydrolyze it.     

Increase of RNase a N-terminus polarity or C-terminus apolarity changes the two domains' propensity to swap and form the two dimeric conformers of the protein

Do the polarities of the N-terminus or the apolarity of the C-terminus of bovine RNase A influence the relative yields of its two 3D domain-swapped dimeric conformers, the N-dimer and C-dimer? We have addressed this question by substituting Ala-4 or Ala-5 with serine (A4S and A5S mutants) or Ser-123 with alanine (S123A mutant) through site-directed mutagenesis. Both the polarity of the N-terminus and the apolarity of the C-terminus of RNase A were, therefore, increased. CD spectra revealed no significant differences between the secondary structures of the mutants and native RNase A. According to thermal denaturation analyses, the A4S and A5S mutants are less stable, and the S123A mutant is more stable than wild type RNase A. By subjecting the mutants under mild or drastic denaturing conditions, side-by-side with native and recombinant RNase A, to a thermally induced oligomerization procedure, the following results were obtained. (i) The N-terminal mutants showed a higher propensity, with respect to the native protein, to form N-dimers under mild unfolding conditions. (ii) The C-terminal mutant showed a higher propensity to form the C-dimer under severely unfolding conditions. These results are discussed in light of the relative stabilities of the various RNase A species under different environmental conditions, and we conclude that the hydrophilic or hydrophobic character of the RNase N-terminus or C-terminus can be an important variable governing the oligomerization of RNase A and possibly other proteins through the 3D domain-swapping mechanism.     

Ribonuclease M5 has few, if any, mRNA substrates in Bacillus subtilis

In Bacillus subtilis, maturation of 5S rRNA is catalyzed by an enzyme called RNase M5. We searched for potential mRNA substrates for RNase M5 by gene array technology, based on the premise that most endonucleolytic cleavages have an effect on the stability of RNA and hence on steady-state levels of expression. Only a handful of genes had significantly altered expression in rnmV mutants compared to wild-type strains that could subsequently be confirmed by Northern blotting. The effect of RNase M5 on the expression of the best candidates, the odhAB and sucCD operons, is indirect, by a mechanism we do not yet understand. We show that an effect of RNase M5 on the expression of the remaining candidate, ctsR, is due to the failure to process the 5S rRNA contained in the rrnW lying directly upstream. We thus conclude that RNase M5 has very few or possibly no mRNA substrates in B. subtilis.     

Identification of the gene encoding the 5S ribosomal RNA maturase in Bacillus subtilis: mature 5S rRNA is dispensable for ribosome function

Over 25 years ago, Pace and coworkers described an activity called RNase M5 in Bacillus subtilis cell extracts responsible for 5S ribosomal RNA maturation (Sogin & Pace, Nature, 1974, 252:598-600). Here we show that RNase M5 is encoded by a gene of previously unknown function that is highly conserved among the low G + C gram-positive bacteria. We propose that the gene be named rnmV. The rnmV gene is nonessential. B. subtilis strains lacking RNase M5 do not make mature 5S rRNA, indicating that this process is not necessary for ribosome function. 5S rRNA precursors can, however, be found in both free and translating ribosomes. In contrast to RNase E, which cleaves the Escherichia coli 5S precursor in a single-stranded region, which is then trimmed to yield mature 5S RNA, RNase M5 cleaves the B. subtilis equivalent in a double-stranded region to yield mature 5S rRNA in one step. For the most part, eubacteria contain one or the other system for 5S rRNA production, with an imperfect division along gram-negative and gram-positive lines. A potential correlation between the presence of RNase E or RNase M5 and the single- or double-stranded nature of the predicted cleavage sites is explored.     

Swapping the domains of exoribonucleases RNase II and RNase R: conferring upon RNase II the ability to degrade ds RNA

RNase II and RNase R are the two E. coli exoribonucleases that belong to the RNase II super family of enzymes. They degrade RNA hydrolytically in the 3' to 5' direction in a processive and sequence independent manner. However, while RNase R is capable of degrading structured RNAs, the RNase II activity is impaired by dsRNAs. The final end-product of these two enzymes is also different, being 4 nt for RNase II and 2 nt for RNase R. RNase II and RNase R share structural properties, including 60% of amino acid sequence similarity and have a similar modular domain organization: two N-terminal cold shock domains (CSD1 and CSD2), one central RNB catalytic domain, and one C-terminal S1 domain. We have constructed hybrid proteins by swapping the domains between RNase II and RNase R to determine which are the responsible for the differences observed between RNase R and RNase II. The results obtained show that the S1 and RNB domains from RNase R in an RNase II context allow the degradation of double-stranded substrates and the appearance of the 2 nt long end-product. Moreover, the degradation of structured RNAs becomes tail-independent when the RNB domain from RNase R is no longer associated with the RNA binding domains (CSD and S1) of the genuine protein. Finally, we show that the RNase R C-terminal Lysine-rich region is involved in the degradation of double-stranded substrates in an RNase II context, probably by unwinding the substrate before it enters into the catalytic cavity.