Messenger and ribosomal RNA hydrolysis by ribonucleases II. Changes in ribonuclease activities and ribosomes of barley leaves during the early stages of powdery mildew infection

We have monitored changes in the properties of two barley (Hordeumvulgare L.) leaf RNases with respect to their action on polysomalmessenger RNA (mRNA) and the RNA of isolated ribosomes duringthe early stages of infection by the powdery mildew fungus (Erysiphegraminis f. sp. hordei). The results presented support the followingconclusions. (i) At 48 hr after inoculation, the pH 5 insolubleRNase undergoes significant changes in its catalytic properties.This is evident from the finding that under limit digestionconditions, the enzyme from inoculated leaves hydrolyzes chloroplastpolysomal mRNA and produces far greater quantities of chloroplastmonosomes than does the corresponding enzyme from healthy leaves.(ii) The acid soluble oligonucleotide fragments produced bythe soluble RNase from healthy and inoculated leaves (at 48hr after inoculation) in the RNA of isolated ribosomes are quantitativelysignificantly different. This suggests a change in the propertiesof the soluble RNase during the initial stages of host-parasiteinteractions. (iii) As early as 24 hr after inoculation, thereis a dramatic change in the distribution of the pH 5 insolubleand soluble RNase cleavage sites in the RNA of ribosomes indicatinga readily detectable conformational change in the ribonucleoproteinparticles. (iv) These changes in the RNases and ribosomes areonly detectable in the susceptible cultivars of barley and notin a cultivar which is genetically resistant to race 3 of thepowdery mildew fungus. (Received January 31, 1980; )     

Impairment of ribosomal subunit synthesis in aminoglycoside-treated ribonuclease mutants of Escherichia coli

The bacterial ribosome is an important target for many antimicrobial agents. Aminoglycoside antibiotics bind to both 30S and 50S ribosomal subunits, inhibiting translation and subunit formation. During ribosomal subunit biogenesis, ribonucleases (RNases) play an important role in rRNA processing. E. coli cells deficient for specific processing RNases are predicted to have an increased sensitivity to neomycin and paromomycin. Four RNase mutant strains showed an increased growth sensitivity to both aminoglycoside antibiotics. E. coli strains deficient for the rRNA processing enzymes RNase III, RNase E, RNase G or RNase PH showed significantly reduced subunit amounts after antibiotic treatment. A substantial increase in a 16S RNA precursor molecule was observed as well. Ribosomal RNA turnover was stimulated, and an enhancement of 16S and 23S rRNA fragmentation was detected in E. coli cells deficient for these enzymes. This work indicates that bacterial RNases may be novel antimicrobial targets.     

Mini-III, a fourth class of RNase III catalyses maturation of the Bacillus subtilis 23S ribosomal RNA

Ribonuclease III (RNase III) type of enzymes are double-stranded RNA (dsRNA)-specific endoribonucleases that have important roles in RNA maturation and mRNA decay. They are involved in processing precursors of ribosomal RNA (rRNA) in bacteria as well as precursors of short interfering RNAs (siRNAs) and microRNAs (miRNAs) in eukaryotes. RNase III proteins have been grouped in three major classes according to their domain organization. In this issue of Molecular Microbiology, Redko et al. identified a novel class of bacterial RNase III, named Mini-III, consisting only of the RNase III catalytic domain and functioning in the maturation of the 23S rRNA in Bacillus subtilis. Its absence from proteobacteria reveals that this step is mechanistically different from the corresponding step in Escherichia coli. The fact that Mini-III orthologues are present in unicellular photosynthetic eukaryotes and in plants opens new opportunities for functional studies of this type of RNases.     

Polyamines,ribonucleases, and the stability of RNA

Summary The polyamines influence the activity of many enzymes involved in the synthesis and degradation of RNA. These organic cations (putrescine, spermidine, spermine) stimulate, for example, many DNA-dependent RNA polymerases and affect both RNA chain elongation and initiation. The polyamines also bind to polynucleotides, forming complexes having, in many cases, physical properties quite distinct from the parent polymer. Some of these complexes are resistent to ribonuclease mediated hydrolysis. However, polyamines alter the activity, as well as the specificity of some RNases, so the actual rate of breakdown of RNA is dependent on the interaction of polyamine with both RNA and enzyme. The hydrolytic rate may also be controlled by the presence of purine homopolymer, which acts to strongly inhibit RNase activity. The addition of polyadenylic acid tracts to the 3 terminus of the RNA substrate, for example, protects the unpolyadenylated portion of the RNA molecule from degradation. Longer segments of poly(A) are more effective in this respect; however, regardless of poly(A) length, low concentrations of spermidine reverse the inhibition of RNase activity, with concomitant rapid degradation of the unpolyadenylated portion of the RNA molecule. Thus, RNA degradation depends not only on the presence of RNase, but on poly(A) length and spermidine concentration as well. Although the relative importance, within the cell, of each of these interactions is not known, the above mechanisms illustrate certain of the complexities and interrelations that may exist for the synthesis and, in particular, the RNase mediated degradation of RNA.A submitted article     

5S ribosomal RNA is contained within a 25 S ribosomal RNA that accumulates in mutants of Escherichia coli defective in processing of ribosomal RNA.

A temperature-sensitive mutant strain of Escherichia coli defective in two RNA processing enzymes, RNase III and RNase E (rnc. rne), fails to produce normal levels of 23 S and 5 S rRNA at the non-permissive temperature. Instead, a molecule larger than 23 S is produced. This molecule, designated 25 S rRNA, can be processed in vitro to produce p5 rRNA. These findings further our understanding of the overall processing events of ribosomal RNA which take place in the bacterial cell.     

Comparison of base specificity and other enzymatic properties of two protozoan ribonucleases from Physarum polycephalum and Dictyostelium discoideum

Base specificity and other enzymatic properties of two protozoan RNases, RNase Phyb from a true slime mold (Physarum polycephalum) and RNase DdI from a cellular slime mold (Dictyostelium discoideum), were compared. These two RNases have high amino acid sequence similarity (83 amino acid residues, 46%). The base specificities of two base recognition sites, The B1 site (base recognition site for the base at 5'-side of scissile phosphodiester bond) and the B2 site (base recognition site for the base at 3'-side of the scissile bond) of the both enzymes were estimated by the rates of hydrolysis of 16 dinucleoside phosphates. The base specificities estimated of B1 and B2 sites of RNase Phyb and RNase DdI were A, G, U > C and A > or = G > C > U, and A > or = G, U > C and G > U > A, C, respectively. The base specificities estimated from the depolymerization of homopolynucleotides and those from the releases of four mononucleotides upon digestion of RNA coincided well with those of the B2 sites of both enzymes. Thus, in these enzymes, the contribution of the B2 site to base specificity seems to be larger than that of the B1 site. pH-stability, optimum temperature, and temperature stability, of both enzymes are discussed considering that RNase Phyb has one disulfide bridge deleted, compared to the RNase DdI with four disulfide bridges.     

PRBP plays a role in plastid ribosomal RNA maturation and chloroplast biogenesis in <Emphasis Type="Italic">Nicotiana benthamiana</Emphasis>

In the present study, we investigated protein characteristics and physiological functions of PRBP (plastid RNA-binding protein) in Nicotiana benthamiana. PRBP fused to green fluorescent protein (GFP) localized to the chloroplasts. Recombinant PRBP proteins bind to single-stranded RNA in vitro, but not to DNA in a double- or a single-stranded form. Virus-induced gene silencing (VIGS) of PRBP resulted in leaf yellowing in N. benthamiana. At the cellular level, PRBP depletion disrupted chloroplast biogenesis: chloroplast number and size were reduced, and the thylakoid membrane was poorly developed. In PRBP-silenced leaves, protein levels of plastid-encoded genes were significantly reduced, whereas their mRNA levels were normal regardless of their promoter types indicating that PRBP deficiency primarily affects translational or post-translational processes. Depletion of PRBP impaired processing of the plastid-encoded 4.5S ribosomal RNA, resulting in accumulation of the larger precursor rRNAs in the chloroplasts. In addition, PRBP-deficient chloroplasts contained significantly reduced levels of mature 4.5S and 5S rRNAs in the polysomal fractions, indicating decreased chloroplast translation. These results suggest that PRBP plays a role in chloroplast rRNA processing and chloroplast development in higher plants.     

Specificity and other properties of three ribonucleases of Tetrahymena pyriformis

Three ribonucleases, RNase I, RNase II and RNase III, were purified from the 109,000 X g supernate of detergent-treated Tetrahymena pyriformis strain W. RNases I and II act optimally at pH 5.5-6.0 and are inhibited by increasing concentrations of salts of monovalent cations. RNase III acts optimally at pH 7.5 and is activated 1.5-fold by millimolar concentrations of ZnSO4 and 5-fold by 50 mM KCl. RNases II and III are activated approximately 100% in the presence of 3 M and 5 M urea respectively. All enzymes are heat-sensitive and acid-resistant. They are endonucleases forming 2',3'-cyclic products. Their base specificity, as tested against ribosomal RNAs of known sequence, is as follows: RNase I hydrolyzes preferentially YpN and secondarily GpN bonds, RNase II is highly specific for RpN bonds, though the preparation can also hydrolyze the UpU sequence. Finally the principal targets of RNase III are YpR sequences and secondarily YpY sequences. A shorthand visualization of base specificity of nucleases in the form of right isosceles triangles is presented. The triangles are constructed by subdividing each of the two perpendicular sides in as many units as the maximum number of times the most abundant dinucleotide appears in all substrates employed and plotting the frequency of hydrolysis of each dinucleotide sequence by the enzyme under study. The proximity of each dinucleotide sequence to the hypotenuse or to one of the perpendicular sides is indicative of its susceptibility or resistance to the enzyme's action.     

Interferon-mediated effect on ribosomal RNA metabolism

Ribosomal RNA (rRNA) has been shown to be involved in the binding of bacterial messenger RNA (mRNA) and an analogous 18 S rRNA · mRNA complex has been reported in eukaryotic systems. Thus, qualitative changes in host rRNA may be involved in the development of the interferon mediated antiviral state, a process thought to involve the inability of host ribosomes to bind and recognize viral mRNA. Data are reported which suggest that trisomy 21 human fibroblasts respond to human interferon with a marked reduction in cytoplasmic rRNA. [³H]Uridine was used to radioactively label the polysomal RNAs for 24 h beginning 12 h after interferon addition. Subsequent sucrose gradient analysis of the phenol or SDS-extracted RNA revealed that the reduction in radioactive rRNA was nearly complete for the 28 S rRNA. In contrast, considerable residual uridine incorporation was found in the 18 S rRNA species. Corollary data suggesting a net increase in mRNA synthesis and a net decrease in protein synthesis are reported.     

Purification and properties of bovine kidney ribonucleases

Two RNases (RNases K1 and K2) were purified from bovine kidney by means of column chromatography on phospho-cellulose, Sephadex G-50, CM-cellulose, heparin-Sepharose, nd agarose-APUP. They were named RNase K1 and RNase K2 in order of elution from the heparin-Sepharose column. The purity of RNase K1 thus obtained was about 90% by SDS-disc electrophoresis. RNase K2 was purified to homogeneity by SDS- and pH 4.3 disc electrophoresis. The yield of RNase K2 was 3.4 mg from 11 kg of kidneys. The antigenic properties of the two bovine renal RNases were studied by Ouchterlony's double diffusion analysis. RNase K1 and RNase A were serologically indistinguishable. RNase K2 did not cross-react immunologically with RNase K1 or RNase A. The molecular weights of these RNases determined by gel-filtration on Sephadex G-50 were 13,400 and 14,600 for RNase K1 and RNase K2, respectively. The pH optima for RNase K1 and RNase K2 were 8.5 and 6.5, respectively. Both RNase K1 and RNase K2 were as acid stable as RNase A. RNase K2 was less heat-stable than RNase K1 and RNase A. Although both renal RNases were pyrimidine nucleotide-specific enzymes, RNase K1 and RNase A were more preferential or cytidylic acid than RNase K2. The chemical composition of RNase K2 was determined. RNase K2, like human urinary RNase Us, contained one tryptophan residue. The N-terminal sequences of RNase K2 and RNase Us were determined by Edman degradation. Rnase K2 had a homologous sequence of about 10 amino acid residues with the sequence of RNase Us, a typical non-secretory RNase, within the N-terminal 30 residues.     

Eukaryotic ribonucleases P/MRP: the crystal structure of the P3 domain

Ribonuclease (RNase) P is a site‐specific endoribonuclease found in all kingdoms of life. Typical RNase P consists of a catalytic RNA component and a protein moiety. In the eukaryotes, the RNase P lineage has split into two, giving rise to a closely related enzyme, RNase MRP, which has similar components but has evolved to have different specificities. The eukaryotic RNases P/MRP have acquired an essential helix‐loop‐helix protein‐binding RNA domain P3 that has an important function in eukaryotic enzymes and distinguishes them from bacterial and archaeal RNases P. Here, we present a crystal structure of the P3 RNA domain from Saccharomyces cerevisiae RNase MRP in a complex with RNase P/MRP proteins Pop6 and Pop7 solved to 2.7 Å. The structure suggests similar structural organization of the P3 RNA domains in RNases P/MRP and possible functions of the P3 domains and proteins bound to them in the stabilization of the holoenzymes' structures as well as in interactions with substrates. It provides the first insight into the structural organization of the eukaryotic enzymes of the RNase P/MRP family.     

Novel role for RNase PH in the degradation of structured RNA

Escherichia coli contains multiple 3' to 5' RNases, of which two, RNase PH and polynucleotide phosphorylase (PNPase), use inorganic phosphate as a nucleophile to catalyze RNA cleavage. It is known that an absence of these two enzymes causes growth defects, but the basis for these defects has remained undefined. To further an understanding of the function of these enzymes, the degradation pattern of different cellular RNAs was analyzed. It was observed that an absence of both enzymes results in the appearance of novel mRNA degradation fragments. Such fragments were also observed in strains containing mutations in RNase R and PNPase, enzymes whose collective absence is known to cause an accumulation of structured RNA fragments. Additional experiments indicated that the growth defects of strains containing RNase R and PNPase mutations were exacerbated upon RNase PH removal. Taken together, these observations suggested that RNase PH could play a role in structured RNA degradation. Biochemical experiments with RNase PH demonstrated that this enzyme digests through RNA duplexes of moderate stability. In addition, mapping and sequence analysis of an mRNA degradation fragment that accumulates in the absence of the phosphorolytic enzymes revealed the presence of an extended stem-loop motif at the 3' end. Overall, these results indicate that RNase PH plays a novel role in the degradation of structured RNAs and provides a potential explanation for the growth defects caused by an absence of the phosphorolytic RNases.     

Why ribonucleases cause death of cancer cells

Molecular properties and possible mechanisms of action of cytotoxic ribonucleases (RNases), potential antitumor therapeutics, are characterized. The analysis of recent publications and own experimental results have allowed the authors, on the one hand, to distinguish cellular components that are responsible for selective activity of exogenous RNases towards malignant cells, and on the other--to identify the contribution of definite molecular determinants to the enzyme cytotoxicity. The predominant effect of the RNase molecule charge on the cell death induction is shown. The RNase cytotoxic effects are caused by catalytic cleavage of available RNA, by products of its hydrolysis, as well as by non-catalytic electrostatic interaction of exogenous enzyme with cell components. Potential targets for RNase action in a cancer cell have been revealed. The role of modulation of the membrane calcium-dependent potassium channels and ras-oncogene functions in the RNase-induced cell damage is defined. The effect of cytotoxic RNases on gene expression via influencing the RNA interference is discussed.     

Purification and properties of magnesium- and manganese-dependent ribonucleases H from chick embryo

Two RNases H, Mg2+- and Mn2+-dependent RNases H, are present in extracts of chick embryo. These RNases H can be separated by phosphocellulose column chromatography. Mg2+-dependent RNase H was purified over 900-fold and Mn2+-dependent RNase H over 1,700-fold from chick embryo extracts. The molecular weight of the purified Mg2+-dependent RNase H was about 40,000 and of the Mn2+-dependent RNase H about 120,000, when estimated by gel filtration. Mg2+-dependent RNase H exhibits maximal activity at pH 9.5, and requires 15 to 20 mM Mg2+ for maximal activity, whereas Mn2+-dependent RNase H is most active at pH 8.5, and is maximally active at the concentration of 0.4 mM Mn2+, and has some activity with Mg2+. Both enzymes require a sulfhydryl reagent for maximal activity. Mn2+-dependent RNase H was inhibited by o-phenanthroline, pyrophosphate, and those polyamines tested, whereas Mg2+-dependent enzyme was not, although it was inhibited by NaF. Both RNases H liberate a mixture of oligonucleotides with 5'-phosphate and 3'-hydroxyl termini endonucleolytically.     

Purification and characterization of three ribonucleases from human kidney: comparison with urine ribonucleases

Three ribonucleases (RNases) with different molecular masses were isolated from human kidney. The enzymes were purified to an electrophoretically homogeneous state, and their respective molecular masses were found to be 18,000 (tentatively named RNase HK-1), 20,000 (RNase HK-2A), and 22,000 (RNase HK-2B) on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Analysis of the amino acid compositions, amino-terminal sequences, and enzymological properties of the enzymes indicate that RNase HK-1 is related to "nonsecretory" RNase, and that RNases HK-2A and HK-2B are both related to "secretory" RNase. Furthermore, RNase HK-1 showed cross-reactivity with an antibody specific to nonsecretory RNase from human urine, whereas RNases HK-2A and HK-2B showed cross-reactivity with another antibody specific to human urine secretory RNase. However, the carbohydrate compositions of RNases HK-2A and HK-2B were markedly different from that of the secretory urine RNase. This finding seems to indicate that the kidney is not the origin of the urine enzyme.     

Why ribonucleases induce tumor cell death

The characteristics and the possible mechanisms of action of cytotoxic ribonucleases (RNases), promising antitumor drugs, are described. Original experimental data and the results of analysis of recent publications have made it possible to identify the cellular components providing for the selective effects of exogenous RNases on tumor cells, on the one hand, and to estimate the contributions of individual molecular determinants to the enzyme cytotoxicity, on the other hand. The predominant effect of the electric charge of the RNase molecule on the induction of cell death has been demonstrated. The cytotoxic effects of RNases are determined by the catalytic cleavage of accessible RNA, the action of the products of its hydrolysis, and the noncatalytic electrostatic interaction of the exogenous enzyme with cell components. Potential RNase targets in a tumor cell and the role of modulation of calcium-dependent potassium channels and the ras oncogene in RNase-induced cell damage are considered. The effect of cytotoxic RNases on gene expression by affecting RNA interference is discussed.Translated from Molekulyarnaya Biologiya, Vol. 39, No. 1, 2005, pp. 3–13.Original Russian Text Copyright © 2005 by Ilinskaya, Makarov.     

On the degradation of intracellular RNA by ribonucleases

The kinetic and the specificity of two RNases purified from the insect. C. capitata have been studied. These two enzymes exhibit preference to degrade large polynucleotides. The alkaline enzyme is located in the soluble cellular fraction and the acid enzyme is also associated to microsomes and lysosomes. A hypothesis about the physiological role of these two insect enzymes in the degradation of the intracellular RNA is proposed.