Studies on extracellular ribonucleases of Ustilago sphaerogena. Characterization of substrate specificity with special reference to purine-specific ribonucleases

Non-coding RNA notations, regulations and interactive resources

An increasing number of non-coding RNAs (ncRNAs) are found to have roles in gene expression and cellular regulations. However, there are still a large number of ncRNAs whose functions remain to be studied. Despite decades of research, the field continues to evolve, with each newly identified ncRNA undergoing processes such as biogenesis, identification, and functional annotation. Bioinformatics methodologies, alongside traditional biochemical experimental methods, have played an important role in advancing ncRNA research across various stages. Presently, over 50 types of ncRNAs have been characterized, each exhibiting diverse functions. However, there remains a need for standardization and integration of these ncRNAs within a unified framework. In response to this gap, this review traces the historical trajectory of ncRNA research and proposes a unified notation system. Additionally, we comprehensively elucidate the ncRNA interactome, detailing its associations with DNAs, RNAs, proteins, complexes, and chromatin. A web portal named ncRNA Hub ( https://bis.zju.edu.cn/nchub/ ) is also constructed to provide detailed notations of ncRNAs and share a collection of bioinformatics resources. This review aims to provide a broader perspective and standardized paradigm for advancing ncRNA research.

Improving RNA modification mapping sequence coverage by LC-MS through a nonspecific RNase U2-E49A mutant

We report the identification and use of a mutant of the purine selective ribonuclease RNase U2 that randomly cleaves RNA in a manner that is directly compatible with RNA modification mapping by mass spectrometry. A number of RNase U2 mutants were generated using site-saturation mutagenesis. The enzyme activity and specificity were tested using oligonucleotide substrates, which revealed an RNase U2 E49A mutant with limited specificity and a tendency to undercut RNA. Using this mutant, RNA digestion conditions were optimized to yield long, overlapping digestion products, which improve sequence coverage in RNA modification mapping experiments. The analytical utility of this mutant was demonstrated by liquid chromatography tandem mass spectrometry (LC-MS/MS) mapping of several modified RNAs where 100% sequence coverage could be obtained using only a single enzymatic digestion. This new mutant facilitates more accurate and efficient RNA modification mapping than traditional highly base-specific RNases that are currently used.

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 alpha-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.

Fungal ribotoxins: molecular dissection of a family of natural killers

RNase T1 is the best known representative of a large family of ribonucleolytic proteins secreted by fungi, mostly Aspergillus and Penicillium species. Ribotoxins stand out among them by their cytotoxic character. They exert their toxic action by first entering the cells and then cleaving a single phosphodiester bond located within a universally conserved sequence of the large rRNA gene, known as the sarcin-ricin loop. This cleavage leads to inhibition of protein biosynthesis, followed by cellular death by apoptosis. Although no protein receptor has been found for ribotoxins, they preferentially kill cells showing altered membrane permeability, such as those that are infected with virus or transformed. Many steps of the cytotoxic process have been elucidated at the molecular level by means of a variety of methodological approaches and the construction and purification of different mutant versions of these ribotoxins. Ribotoxins have been used for the construction of immunotoxins, because of their cytotoxicity. Besides this activity, Aspf1, a ribotoxin produced by Aspergillus fumigatus, has been shown to be one of the major allergens involved in allergic aspergillosis-related pathologies. Protein engineering and peptide synthesis have been used in order to understand the basis of these pathogenic mechanisms as well as to produce hypoallergenic proteins with potential diagnostic and immunotherapeutic applications.

Anomalous electrophoretic behavior of a very acidic protein: ribonuclease U2

Ribonuclease U2 is a low-molecular-weight acidic protein with three disulfide bridges. This protein displays an anomalous electrophoretic behavior on standard SDS-PAGE. The electrophoretic mobility of the nonreduced protein roughly corresponds to its molecular mass while the migration of the reduced protein would be in accordance with the expected molecular mass of the protein dimer. This study reveals that the protein does not bind SDS under the SDS-PAGE conditions, its electrophoretic mobility being only determined by its electrostatic charge and hydrodynamic properties. In addition, the nonreduced protein cannot be blotted to a membrane. Unfolding of the protein upon reduction of its disulfide bridges enables electrotransference to membranes due to a restricted diffusion along the electrophoresis gel.

Determination of oligonucleotide composition from mass spectrometrically measured molecular weight

Extensive calculations for molecular mass versus subunit composition have been made for oligonucleotides from RNA and DNA to determine the extent to which base compositions might be derived from mass spectrometrically determined molecular weights. In the absence of compositional constraints (e.g., any numbers of A, U, G, C), measurement of molecular weight leads to only modest restrictions in allowable number of base compositions; however, if the compositional value for any one residue is known, such as from selective chemical modification or enzymatic cleavage, the number of allowable base compositions becomes unexpectedly low. For example, hydrolysis of RNA by ribonuclease T1 produces oligonucleotides for which G=1, for which all base compositions can be uniquely specified up to the 14-mer level, solely by measurement of mass to within ±0,01%. The effects of methylation, phosphorylation state of nucleotide termini, and knowledge of chain length on the determination of subunit composition are discussed.

A DNA-dependent RNA synthesis by wheat-germ RNA polymerase II insensitive to the fungal toxin alpha-amanitin

Wheat-germ RNA polymerase II is able to catalyse a DNA-dependent reaction of RNA synthesis in the presence of a high concentration (1 mg/ml) of the fungal toxin alpha-amanitin. This anomalous reaction is specifically directed by single-stranded or double-stranded homopolymer templates, such as poly(dC) or poly(dC).poly(dG), and occurs in the presence of either Mn2+ or Mg2+ as the bivalent metal cofactor. In contrast, the transcription of other synthetic templates, such as poly(dT), poly(dA).poly(dT) or poly[d(A-T)] is completely abolished in the presence of 1 microgram of alpha-amanitin/ml, in agreement with well-established biochemical properties of class II RNA polymerases. Size analysis of reaction products resulting from transcription of (dC)n templates of defined lengths suggests that polymerization of RNA chains proceeds through a slippage mechanism. The fact that alpha-amanitin does not impede this synthetic reaction implies that the amatoxin interferes with the translocation of wheat-germ RNA polymerase II along the DNA template.

Glu 46 of ribonuclease T1 is an essential residue for the recognition of guanine base

The Glu 46 of ribonuclease T1, which is assumed to interact with Nl of the guanine residue in RNA by a hydrogen bond from the result of X-ray analysis, was changed to alanine by site-directed mutagenesis and its function examined. The nucleolytic activity of the Ala 46 mutant enzyme against pGpC decreased to 0.4% of that of the wild-type enzyme, on the other hand its activity against pApC increased. This result suggests that the Glu 46 is essential for the recognition of the guanine base but that it also interferes with the recognition of the adenine base.

Comparison of the primary structures of ribonuclease U2 isoforms

The primary structures of the two isoforms of ribonuclease U2, RNAases U2-A and U2-B, were analysed and compared with each other. Among the chymotryptic peptides obtained from the reduced and S-carboxymethylated enzymes, only peptides C-3 were different from each other in terms of chromatographic behaviour on reverse-phase h.p.l.c. On the basis of chemical analyses of these peptides, it was shown that RNAase U2-B had an isopeptide bond in which Asp-32 was linked to Gly-33 through the beta-carboxy group in its side chain instead of the alpha-carboxy group. Deamidation of Asn-32 in RNAase U2-A led to the formation of this unusual linkage. The previously reported sequence of RNAase U2 [Sato & Uchida (1975) Biochem. J. 145, 353-360] was corrected by changing amino acid residues at eight different positions and by inserting an asparagine residue at position 32. The numbering of the positions of amino acid residues located downstream of Asn-32 was therefore shifted by 1. Accordingly, RNAase U2-A was shown to be composed of 114 amino acid residues.

Inquiries into the structure-function relationship of ribonuclease T1 using chemically synthesized coding sequences

The genes for ribonuclease T1 and its site-specific mutants were chemically synthesized and introduced to Escherichia coli. All enzymes were fusion products produced by joining the synthetic gene at specific restriction sites to the synthetic gene for human growth hormone in a plasmid containing the E. coli trp promoter. The fusion protein from this plasmid contained 66% of the amino-terminal sequences of the human growth hormone, which were recognizable immunologically. RNase T1 or its mutants were cleaved from the fusion protein with cyanogen bromide. The synthetic RNase T1 endowed with the revised wild-type triad Gly-Ser-Pro, residues 71-73, was fully functional, readily hydrolyzing pGpC bonds, whereas a mutant enzyme having the originally reported, erroneous triad Pro-Gly-Ser was totally inactive. Various amino acid substitutions were also introduced to the guanosine recognition region comprised of residues 42-45, Tyr-Asn-Asn-Tyr. Substitution of either of the tyrosine residues noted above with phenylalanine had no dramatic effect on the enzyme's function. Replacement of asparagine-43 with arginine or alanine also caused only a small change in the hydrolyzing activity--a mutant enzyme maintained greater than 50% of the wild-type activity. In sharp contrast, when aspartic acid or alanine was substituted for asparagine-44, the activity was dramatically reduced to a few percent of the wild-type activity.

Nucleotide sequences at the 5' termini of reovirus mRNA's

During in vitro synthesis of reovirus mRNA by viral cores, methyl groups from S-adenosylmethionine are incorporated only into 5'-terminal cap structures, i.e., m7GpppGmCp.... Thus, mRNA synthesized in the presence of S-adenosyl-[methyl-3H]methionine is 3H labeled specifically at the 5' terminus. This circumstance was exploited in the determination of 5'-terminal nucleotide sequences. Seven 5'-terminal fragments derived by complete RNase T1, digestion of methyl-3Hlabeled mRNA were partially degraded with RNase T2, and the products were separated by electrophoresis-homochromatography. From the patterns formed by the methyl-3H-labeled RNase T2 products, the sequences of the seven RNase T1-generated fragments were deduced. All seven fragments started with the sequence m7GpppGmCUA, after which the sequences diverged, with a tendency to be either U-rich or A-rich. Their chain lengths ranged from 7 to 10 nucleotides (excluding the m7G residue), and none of them contained an initiator AUG triplet. The sequences obtained support the hypothesis that virion-associated oligonucleotides arise through abortive transcription of the viral genome. There is no apparent 5'-terminal sequence feature distinctive of early versus late mRNA species within the small-mRNA size class.

Use of specific endonuclease cleavage in RNA sequencing

Nonradioactive RNA fragments may be sequenced by incorporation of (3H)-label into 3'-terminal positions, controlled digestion with specific ribonucleases, and separation according to size of the digestion products on polyethyleneimine- (PEI-) cellulose thin layers. This combination of techniques allows one to measure accurately distances of specific cleavage sites from the labeled terminal positions. The cleavage specificities of RNases T1, U2, and A are utilized to identify the positions of G, A, and pyrimidine residues respectively. C and U may be distinguished by mobility differences on PEI-cellulose thin layers at ph 2.6. The procedure is simple, rapid, and highly sensitive; as little as 0.5 - 1 microgram of a RNA of the size of tRNA will be needed to sequence all fragments in a complete RNase digest.

Sequence analysis of T1 ribonuclease fragments of 18S ribosomal RNA by 5'-terminal labeling, partial digestion, and homochromatography fingerprinting

The method employed to determine the sequence of a T1 RNase fragment, A-A-A-A-A-U-A-A-C-A-A-U-A-C-A-Gp, from Novikoff rat hepatoma 18S ribosomal RNA is described. This method is applicable to any oligoribonucleotide produced by specific endonucleases that leave the newly cleaved 5'-end free for labeling with polynucleotide kinase and gamma-(32p)-ATP. The (32p)-labeled oligoribonucleotide is subjected to partial endonucleolytic digestion and fractionated by two-dimensional homochromatography fingerprinting. The nucleotide sequence is determined by following mobility shifts of the labeled and partially digested oligoribonucleotides in homochromatography fingerprinting.

A modified uridine in the anticodon of E. coli tRNA I Tyr su + oc

The anticodon of an ochre-suppressing derivative of E. coli tRNA I Tyr, previously identified as UUA, can contain a modified uridine (U+) in the first position. The novel modified nucleotide has been identified by two-dimensional thin layer chromatography following RNase T2 digestion of anticodon-containing fragments. Up+ is found in less than stoichiometric molar yields in preparations of tRNA I Tyr su + oc. The electrophoretic mobility of Up+ is the same as Up at pH 3.5 and pH 7.5. U+ probably does not contain sulfur since it cannot be labeled with 35S in vivo incorporation experiments.

On the interaction of ribonuclease U-2 and substrate analogues

1. The interaction of ribonuclease U-2 (RNAase U-2) with its substrate analogues has been investigated by a gel filtration method. At pH 4.5 and 30 degrees C, the apparent binding strength of the substrate analogues was in the following order; adenylate greater than guanylate greater than inosylate greater than cytidylate among 2'-nucleotides and 2'- greater than 3'- greater than 5'- among adenylate isomers. The formation of an equimolar complex of RNAase U-2 and 2'-nucleotide was indicated from the Scatchard plot. 2. The interaction of RNAase U-2 with 2'-adenylate or 2'-guanylate was observed spectrophotometrically. The complex of RNAase U-2 and 2'-adenylate yielded not only an absorption difference spectrum having a broad positive peak at 280 to 285 nm and a negative trough at 256 nm but also a circular dichroic difference spectrum having a positive peak at around 250 nm and a negative trough at around 290 nm. The complex of RNAase U-2 and 2'-guanylate gave a similar difference spectrum to that of the RNAase T-1 - 3'-guanylate complex, in absorption as well as in circular dichroism.

The amino acid sequence of ribonuclease U2 from Ustilago sphaerogena

1. RNAase (ribonuclease) U2, a purine-specific RNAase, was reduced, aminoethylated and hydrolysed with trypsin, chymotrypsin and thermolysin. On the basis of the analyses of the resulting peptides, the complete amino acid sequence of RNAase U2 was determined, 2. When the sequence was compared with the amino acid sequence of RNAase T1 (EC 3.1.4.8), the following regions were found to be similar in the two enzymes; Tyr-Pro-His-Gln-Tyr (38-42) in RNAase U2 and Tyr-Pro-His-Lys-Tyr (38-42) in RNAase T1, Glu-Phe-Pro-Leu-Val (61-65) in RNAase U2 and Glu-Trp-Pro-Ile-Leu (58-62) in RNAase T1, Asp-Arg-Val-Ile-Tyr-Gln (83-88) in RNAase U2 and Asp-Arg-Val-Phe-Asn (76-81) in RNAase T1 and Val-Thr-His-Thr-Gly-Ala (98-103) in RNAase U2 and Ile-Thr-His-Thr-Gly-Ala (90-95) in RNAase T1. All of the amino acid residues, histidine-40, glutamate-58, arginine-77 and histidine-92, which were found to play a crucial role in the biological activity of RNAase T1, were included in the regions cited here. 3. Detailed evidence for the amino acid sequence of the sequence of the proteins has been deposited as Supplementary Publication SUP 50041 (33 PAGES) AT THE British Library (Lending Division)(formerly the National Lending Library for Science and Technology), Boston Spa, Yorks. LS23 7BQ, U.K., from whom copies can be obtained on the terms indicated in Biochem. J. (1975), 145, 5.

Poly(A) polymerase activity in reovirus

An enzymatic activity which synthesized oligo(A) in vitro was found in highly purified reovirus. The poly(A) polymerase activity was dependent on Mn(2+) and utilized only ATP, whereas the virion-associated RNA polymerase required all four ribonucleoside triphosphates and Mg(2+). Oligo(A) synthesis was demonstrated with complete virions and infectious subviral particles derived from virus by limited chymotrypsin digestion but not with cores, a product of extensive chymotrypsin digestion of virus. The enzymatic product and the oligo(A) from purified virions were isolated by binding to oligo(dT)-cellulose columns. Most of the in vitro product was similar in size and structure to the oligo(A) from purified virions by the criteria of gel electrophoresis, DEAE-cellulose chromatography, end-group analysis, and sensitivity to RNase. The evidence suggests that oligo(A) synthesis is mediated by the poly(A) polymerase during a late step in viral morphogenesis and may result from an alternative activity of the virion-associated transcriptase.

Occurrence of uridylate-rich oligonucleotide regions in heterogeneous nuclear RNA of HeLa cells

Heterogeneous nuclear RNA molecules from HeLa cells contain a specific segment of about 30 nucleotides length that is largely (about 80%) uridylic acid. This oligo(U) segment is located predominantly in the larger (70S-90S) heterogeneous nuclear RNA molecules, and is essentially absent in messenger RNA and 45S ribosomal precursor RNA molecules. The oligo(U) hybridizes rapidly to cellular DNA, suggesting that it is transcribed from the repeated regions of the DNA.

Nucleotide sequences in bacteriophage ribonucleic acid. The eighth hopkins memorial lecture

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The nucleotide sequences of some large ribonuclease T 1 products from bacteriophage R17 ribonucleic acid

A method of ;fingerprinting' high-molecular-weight (32)P-labelled RNA species, using a two-dimensional thin-layer-chromatographic separation of ribonuclease T(1) digestion products, has been applied to RNA from the Escherichia coli bacteriophage R17. The ;fingerprinting' technique, besides giving a unique pattern that can be used as a characterization of the RNA, has made it possible to isolate a number of the larger oligonucleotides and to determine their nucleotide sequences.