Primary Structure of a Base Non-specific and Adenylic Acid Preferential Ribonuclease from the Fruit Bodies of Lentinus edodes

The complete primary structure of a base non-specific and adenylic acid preferential RNase (RNase Le₂) from the fruit bodies of Lentinus edodes was analyzed. The sequence was mostly determined by analysis of the peptides generated by V₈ protease digestion and BrCN cleavage (including α-chymotryptic, and V₈ protease digest of BrCN fragments). It consists of 239 amino acid residues. The molecular weight is 25831. The location of 10 half cystine residues were almost superimposable on those of known fungal RNases of the RNase T₂ family. The sequence homologies between RNase Le₂ and four known fungal RNases of the RNase T₂ family, RNase T₂, RNase M, RNase Trv, and RNase Rh, are 102, 103, 109, and 74, respectively. The homologous sequences are concentrated around the three histidines, which are supposed to form the active site of RNase T₂ family RNases.     

Fungal extracellular ribonucleases (Review)

Results of studies of certain fungal extracellular ribonucleases mainly isolated from representatives of the genera Aspergillus and Penicillium are summarized. The isolation of these enzymes in highly purified states in the 1970-1980s strongly stimulated further studies of their structure, functions, and mechanisms of action. This also promoted the use of ribonucleases as catalysts in oligoribonucleotide syntheses and as objects of comparative and evolutionary biochemistry and other research works. Results of studies of the primary, secondary, and spatial structures of guanyl-specific fungal ribonucleases are reviewed. These studies revealed a high homology within the subfamilies of fungal, bacterial, and actinomycete RNases. Characteristics of the nonspecific Pb2 RNase are considered.     

Synthetic constructs functionally mimicking ribonuclease A

The mechanism of hydrolysis of RNA substrates—diribonucleoside monophosphate CpA and decaribonucleotide UUCAUGUAAA—by chemical constructs functionally mimicking ribonuclease A was studied. It is shown that RNA cleavage by chemical RNases 2L2 and 2D3 proceeds similar to the RNase A-induced RNA hydrolysis through 2′,3′-cyclophosphate as an intermediate product. A comparison of hydrolyses of CpA in water and D₂O revealed an isotope effect (K _H/K _D=2.28), which implies acid-base catalysis at the limiting stage of the reaction. Two feasible mechanisms of RNA hydrolysis by chemical RNases (linear and adjacent) are discussed.     

Expression of Nicotiana glutinosa Ribonucleases in Escherichia coli

We previously isolated from Nicotiana glutinosa leaves three distinct cDNA clones, NGR1, NGR2, and NGR3, encoding a wound-inducible RNase NW, and putative RNases NGR2 and NGR3, respectively. In this study, we produced RNases NW and NGR3 in Escherichia coli and purified them to homogeneity. RNase NGR3 had non-absolute specificity toward polynucleotides, although RNase NW preferentially cleaved polyinosinic acid (Poly I). Both RNases NW and NGR3 were more active toward diribonucleoside monophosphates ApG, CpU, and GpU. Furthermore, kinetic parameters for RNase NW (K _m, 0.778 mM and k _cat, 1938 min^?1) and RNase NGR3 (K _m, 0.548 mM and k _cat, 408 min^?1) were calculated using GpU as a substrate.     

Ribonucleases of different origins with a wide spectrum of medicinal applications

Ribonucleases (RNases) are a type of nucleases that catalyze the degradation of RNA into smaller components. They exist in a wide range of life forms from prokaryotes to eukaryotes. RNase-controlled RNA degradation is a determining factor in the control of gene expression, maturation and turnover, which are further associated with the progression of cancers and infectious diseases. Over the years, RNases purified from multiple origins have drawn increasing attention from medical scientists due to their remarkable antitumor properties. In this review, we present a brief summary of the representative RNases of fungal, bacterial, plant, and animal origins and outline their potential medicinal value in the treatment of tumor and AIDS. Among them, the most clinically promising RNases are mushroom RNases, Binase and Barnase from bacteria, ginseng RNases, and Onconase from frog (Rana pipiens). Fast developing protein engineering of RNases, which display more potent cytotoxic activity on and greater selectivity for malignant cells, has also aroused the interest of researchers. The multiple anti-cancer mechanisms of RNases are also included. To sum up, these inspiring studies unveil a new perspective for RNases as potential therapeutic agents.     

Distribution of a Kidney Acid-ribonuclease-like Enzyme and the Other Ribonucleases in Bovine Organs and Body Fluids

To determine the distribution of a kidney acid RNase (RNase K₂) and other RNases, the levels of RNase K₂, RNase A, and seminal RNase (RNase Vs₁ in bovine tissues and body fluids were measured by enzyme immunoassay. The crude extracts of several tissues and body fluids were fractionated by phospho-cellulose column chromatography. The enzymatic activities at pH 7.5 and 6.0 and enzyme contents of each tube were measured by enzyme assay and enzyme immunoassay, respectively. In the pancreas, parotid gland, and heart, most RNase activity was due to a single peak of RNase A, but a small amount of RNase K₂ was always observed. In the kidney, there was about 5 times as much RNase K₂ as RNase A. In the lung, although RNase K₂ and RNase A were the major components, there are another two alkaline RNase peaks. In the spleen and liver, there are four RNases, two acid RNases, one of which is RNase K₂, and two alkaline RNases including RNase A. A new acid RNase (non RNase K₂-acid RNase) from both organs was immunologically the same. In serum, there are at least four RNases. By partial purification of serum RNases by phosphocellulose and heparin-Sepharose column chromatographies, at least 4 RNases, RNase A, RNase K₂ and the other two alkaline RNases, one of which is immunologically indistinguishable from liver alkaline RNase, were confirmed. The other serum alkaline RNase was immunologically related to lung and spleen alkaline RNases. In conclusion, in bovine tissues and body fluids there are at least 7 types of pyrimidine-base-specific RNases: brain RNase, seminal RNase, RNase A, RNase K₂, an acid RNase (RNase BSPJ, an alkaline RNase (RNase BL₄), and another alkaline RNase in serum.     

Tomato T2 ribonuclease LE is involved in the response to pathogens

T2 ribonucleases (RNases) are RNA-degrading enzymes that function in various cellular processes, mostly via RNA metabolism. T2 RNase-encoding genes have been identified in various organisms, from bacteria to mammals, and are most diverse in plants. The existence of T2 RNase genes in almost every organism suggests an important biological function that has been conserved through evolution. In plants, T2 RNases are suggested to be involved in phosphate scavenging and recycling, and are implicated in defence responses to pathogens. We investigated the function of the tomato T2 RNase LE, known to be induced by phosphate deficiency and wounding. The possible involvement of LE in pathogen responses was examined. Expression analysis showed LE induction during fungal infection and by stimuli known to be associated with pathogen inoculation, including oxalic acid and hydrogen peroxide. Analysis of LE-suppressed transgenic tomato lines revealed higher susceptibility to oxalic acid, a cell death-inducing factor, compared to the wild type. This elevated sensitivity of LE-suppressed lines was evidenced by visual signs of necrosis, and increased ion leakage and reactive oxygen species levels, indicating acceleration of cell death. Challenge of the LE-suppressed lines with the necrotrophic pathogen Botrytis cinerea resulted in accelerated development of disease symptoms compared to the wild type, associated with suppressed expression of pathogenesis-related marker genes. The results suggest a role for plant endogenous T2 RNases in antifungal activity.     

Growth inhibition of suspension cultured plant cells by ribonucleases

Extracellular, stylar RNases (S-RNases) are produced by self-incompatible, solanaceous plants, such asNicotiana alata, and are thought to be involved in selfpollen rejection by acting selectively as toxins to selfpollen. In this study, the toxicity of RNases to other plant cells was tested by culturing cells ofN. alata andN. plumbaginifolia in the presence ofS-RNases fromN. alata. The growth of cultured cells ofN. plumbaginifolia was inhibited by theS-RNases, but viability was not affected. Growth of cultured cells of oneN. alata selfincompatibility genotype was inhibited by twoS-RNases, indicating that inhibition was not allele specific. Comparisons with the effects of inactivated RNase and other proteins, suggest that the inhibition of growth byS ₂-RNase was partly, but not wholly, due to RNase activity. Heat-denaturedS ₂-RNase was a very effective inhibitor of cell growth, but this inhibitory activity may be a cell surface phenomenon.     

Identification of NoxD/Pro41 as the homologue of the p22phox NADPH oxidase subunit in fungi

NADPH oxidases (Nox) are membrane complexes that produce O₂^?. Researches in mammals, plants and fungi highlight the involvement of Nox‐generated ROS in cell proliferation, differentiation and defense. In mammals, the core enzyme gp91^phox/Nox2 is associated with p22^phox forming the flavocytochrome b₅₅₈ ready for activation by a cytosolic complex. Intriguingly, no homologue of the p22^phox gene has been found in fungal genomes, questioning how the flavoenzyme forms. Using whole genome sequencing combined with phylogenetic analysis and structural studies, we identify the fungal p22^phox homologue as being mutated in the Podospora anserina mutant IDC⁵⁰⁹. Functional studies show that the fungal p22^phox, PaNoxD, acts along PaNox1, but not PaNox2, a second fungal gp91^phox homologue. Finally, cytological analysis of functional tagged versions of PaNox1, PaNoxD and PaNoxR shows clear co‐localization of PaNoxD and PaNox1 and unravel a dynamic assembly of the complex in the endoplasmic reticulum and in the vacuolar system.     

The ribonucleases J1 and J2 are essential for growth and have independent roles in mRNA decay in Streptococcus pyogenes

The paralogous ribonucleases J1 and J2, recently identified in Bacillus subtilis, have both endoribonucleolytic and 5′‐to‐3′ exoribonucleolytic activities and participate in degradation and regulatory processing of mRNA. RNases J1 and J2 have partially overlapping target specificities, but only RNase J1 is essential for B. subtilis growth. Because mRNA decay is important in regulation of virulence factors of Streptococcus pyogenes (the group A streptococcus, GAS), we investigated the role of these newly described RNases in GAS. We found that conditional mutants for both RNases J1 and J2 require induction for growth, so we conclude that, unlike the case in B. subtilis, both of these RNases are essential for GAS growth, and therefore their functions are not redundant. We compared decay of representatives of the two classes of messages we had previously identified: Class I, which decay rapidly in exponential and stationary phase of growth (hasA and gyrA), and Class II, which are stable in stationary phase and exhibit a biphasic decay curve in exponential phase (sagA and sda). We report that RNases J1 and J2 affect the rate of decay of Class I messages and the length of the first phase in decay of Class II messages.     

Detection and inheritance of stylar ribonucleases associated with incompatibility alleles in apricot

 Stylar proteins were surveyed by non-equilibrium pH gradient electrofocusing to identify S-RNases associated with gametophytic self-incompatibility in nine apricot cultivars. RNase activities associated with the alleles of incompatibility S ₁ , S ₂ , S ₅ , and S ₆ and with the allele of compatibility Sc were clearly identified. Two other bands that we considered related to the alleles S ₃ and S ₄ were unique to cultivars Sunglo and Harcot, respectively. Two generations of 17 seedlings from the cross Moniquí× Pepito and 38 from Gitano × Pepito were used to determine the inheritance of the S-RNases. Inheritance of these RNase bands followed the expected segregation ratios and the band combinations correlated perfectly with the known self-incompatibility status of the seedlings determined after self-pollination and observation of pollen tube growth. All evidence presented in this study strongly suggests that RNases are associated with gametophytic self-incompatibility of apricot and that RNases may be the S-gene products. This is the first report identifying S-RNases and describing the inheritance of these S-RNases in apricot. Received: 19 February 1998 / Revision accepted: 2 April 1998     

Influence of key residues on the heterologous extracellular production of fungal ribonuclease U2 in the yeast Pichia pastoris

Ribonuclease U2, secreted by the smut fungus Ustilago sphaerogena, is a cyclizing ribonuclease that displays a rather unusual specificity within the group of microbial extracellular RNases, best represented by RNase T1. Superposition of the three-dimensional structures of RNases T1 and U2 suggests that the RNase U2 His 101 would be the residue equivalent to the RNase T1 catalytically essential His 92. RNase U2 contains three disulfide bridges but only two of them are conserved among the family of fungal extracellular RNases. The non-conserved disulfide bond is established between Cys residues 1 and 54. Mispairing of the disulfide network due to the presence of two consecutive Cys residues (54 and 55) has been invoked to explain the presence of wrongly folded RNase U2 species when produced in Pichia pastoris. In order to study both hypotheses, the RNase U2 H101Q and C1/54S variants have been produced, purified, and characterized. The results obtained support the major conclusion that His 101 is required for proper protein folding when secreted by the yeast P. pastoris. On the other hand, substitution of the first Cys residue for Ser results in a mutant version which is more efficiently processed in terms of a more complete removal of the yeast α-factor signal peptide. In addition, it has been shown that elimination of the Cys 1–Cys 54 disulfide bridge does not interfere with RNase U2 proper folding, generating a natively folded but much less stable protein.     

Distribution of P1 Type Nuclease in the Genus Penicillium

P₁ type nuclease, which hydrolyzes RNA and heat-denatured DNA completely into 5’-mononucleotides and also shows 3’-nucleotidase activity, was widely distributed among various species belonging to the genus Penicillium such as P. expansum, P. notatum, P. steckii and P. meleagrinum. P₁ type nucleases isolated from these strains were produced in a form of complex with malonogalactan when molds were grown on wheat bran. These enzymes showed similar characters in heat-stability (stable at 60°C), temperature optimum (60 to 70°C for RNA and heat denatured DNA, and 70°C for 3’-AMP) and sensitivity to EDTA. The enzymes from P. steckii and P. expansum were immunologically co-related to nuclease P₁.

In addition, many strains of Penicillium produced base-nonspecific RNases forming 3’-mononucleotides via 2’: 3 ’-cyclic nucleotides. These RNases showed similarity in heat-lability (completely inactivated at 60°C), temperature optimum (45 to 50°C), sensitivity to Zn²⁺ and Cu²⁺, and relative hydrolysis rate toward 2’: 3’-cyclic nucleotides (A?C>U?G).     

An F-box gene linked to the self-incompatibility (S) locus of Antirrhinum is expressed specifically in pollen and tapetum

In many flowering plants, self-fertilization is prevented by an intraspecific reproductive barrier known as self-incompatibility (SI), that, in most cases, is controlled by a single multiallelic S locus. So far, the only known S locus product in self-incompatible species from the Solanaceae, Scrophulariaceae and Rosaceae is a class of ribonucleases called S RNases. Molecular and transgenic analyses have shown that S RNases are responsible for pollen rejection by the pistil but have no role in pollen expression of SI, which appears to be mediated by a gene called the pollen self-incompatibility or Sp gene. To identify possible candidates for this gene, we investigated the genomic structure of the S locus in Antirrhinum, a member of the Scrophulariaceae. A novel F-box gene, AhSLF-S ₂, encoded by the S ₂ allele, with the expected features of the Sp gene was identified. AhSLF-S ₂ is located 9 kb downstream of S ₂ RNase gene and encodes a polypeptide of 376 amino acids with a conserved F-box domain in its amino-terminal part. Hypothetical genes homologous to AhSLF-S ₂ are apparent in the sequenced genomic DNA of Arabidopsis and rice. Together, they define a large gene family, named SLF (S locus F-box) family. AhSLF-S ₂ is highly polymorphic and is specifically expressed in tapetum, microspores and pollen grains in an allele-specific manner. The possibility that Sp encodes an F-box protein and the implications of this for the operation of self-incompatibility are discussed.     

ABA may affect the dormancy in triticale caryopses by inhibition of embryo class I RNases,enzymes involved in P<Subscript>i</Subscript> release

The main objective of this study was to analyze the differences in profiles of RNase activities from triticale embryos (Triticosecale, cv. Ugo) between dormant and non-dormant caryopses and to determine the influence of exogenous abscisic acid (ABA) on the activities of these enzymes. The major RNase from the examined tissue was detected following SDS-PAGE, with substrate-based gel assay, described by Yen and Green (Plant Physiol 97:1487–1493, 1991). The activities of enzymes were characterized according to their pH optima, ion dependence, EDTA sensitivity and DNase activity. In embryos with arrested growth (in a natural way by dormancy or artificially by ABA treatment), the activity of two enzymes—24 and 27 kDa—belonging to class I RNases was completely inhibited, whereas that of two other RNases of this family—23 and 25 kDa—was detectable. However, the activity of the class I ribonucleases (enzymes responsible for cellular P_i release) was very low. Moreover, in contrast with non-dormant caryopses, imbibing embryos of dormant or ABA-treated seeds contained 13- and 14-kDa enzymes. These enzymes have not been classified so far, and their specific properties are different from the generally accepted properties of ribonucleolytic enzymes. In addition to the above results, the P_i content in the analyzed samples was determined by the Ames (Methods Enzymol 8:115–118, 1966) method. The results suggest a very low and constant level of inorganic phosphate in dormant samples as well as an evidently decreasing P_i content in embryos under the influence of ABA treatment. The inhibition of the class I RNases activity induced by abscisic acid implies that one of the roles of ABA in seed dormancy may consist in arresting the catabolic release of P_i, which results in retarding the embryo’s growth.     

Three RNases in Senescent and Nonsenescent Wheat Leaves : Characterization by Activity Staining in Sodium Dodecyl Sulfate-Polyacrylamide Gels

We have described three RNases in wheat leaves (Triticum aestivum L. cv Chinese Spring) and developed assays for measuring each RNase individually in crude leaf extracts. We initially used activity staining in sodium dodecyl sulfate-polyacrylamide gels to characterize RNases in extracts of primary and flag leaves. We thus identified acid RNase (EC 3.1.27.1, here designated RNase WL_A), and two apparently novel enzymes, designated RNases WL_B and WL_C. RNase WL_B activity displays a distinctive isozyme pattern, a molecular mass of 26 kilodaltons (major species), a broad pH range with an optimum near neutrality, insensitivity to EDTA, and stimulation by moderate concentrations of KCl and by MgCl₂. RNase WL_C activity exhibits a molecular mass of 27 kilodaltons, a neutral pH optimum, insensitivity to EDTA, and inhibition by KCl, MgCl₂, and tri-(hydroxymethyl)aminomethane. Based on distinctive catalytic properties established in gels, we designed conventional solution assays for selective quantitation of each RNase activity. We used the assays to monitor the individual RNases after gel filtration chromatography and native gel electrophoresis of extracts. In accompanying work, we used the assays to monitor RNases WL_A, WL_B, and WL_C, which are present in senescent and nonsenescent leaves, during the course of leaf senescence.     

Ubiquitin–proteasome‐mediated degradation of S‐RNase in a solanaceous cross‐compatibility reaction

Many plants have a self‐incompatibility (SI) system in which the rejection of self‐pollen is determined by multiple haplotypes at a single locus, termed S. In the Solanaceae, each haplotype encodes a single ribonuclease (S‐RNase) and multiple S‐locus F‐box proteins (SLFs), which function as the pistil and pollen SI determinants, respectively. S‐RNase is cytotoxic to self‐pollen, whereas SLFs are thought to collaboratively recognize non‐self S‐RNases in cross‐pollen and detoxify them via the ubiquitination pathway. However, the actual mechanism of detoxification remains unknown. Here we isolate the components of a SCF^SLF (SCF = SKP1‐CUL1‐F‐box‐RBX1) from Petunia pollen. The SCF^SLF polyubiquitinates a subset of non‐self S‐RNases in vitro. The polyubiquitinated S‐RNases are degraded in the pollen extract, which is attenuated by a proteasome inhibitor. Our findings suggest that multiple SCF^SLF complexes in cross‐pollen polyubiquitinate non‐self S‐RNases, resulting in their degradation by the proteasome.     

Characterization of Ribonucleases from Culture Medium of Lentinus edodes

Lentinus edodes (shiitake) cultivated in potato dextrose medium produced five RNases in the culture filtrate. The two major RNases (RNase Le37 and RNase Le45) were highly purified and their molecular masses, base specificities, N-terminal amino acid sequences, and amino acid compositions were analyzed and compared to RNase Le2 isolated from the fruit bodies of the same mushroom. RNase Le37 and RNase Le45 are base non-specific and adenylic acid preferential RNases like RNase Le2 and their N-terminal sequences are very similar to RNase Le2, but they are glycoproteins and their amino acid compositions are significantly different from that of RNase Le2. In addition to these enzymes, a guanylic acid-specific RNase with a molecular mass 13 kDa was partially purified. Since RNase Le2, which has very similar N-terminal sequence to RNase Le 37 and RNase Le 45, was not excreted from the mycelia, the analysis of the structures of these two excreted RNase may shade a light on the mechanism of excretion of RNases in this organism.