Primary structure of a base non-specific and adenylic acid preferential ribonuclease from Aspergillus saitoi

The complete primary structure of a base non-specific and adenylic acid preferential RNase (RNase M) from Aspergillus saitoi was determined. The sequence was determined by analysis of the peptides generated by digestion of heat-denatured RNase M with lysylendopeptidase, and the peptides generated from RCM RNase M by digestion with staphylococcal V8 protease or chemical cleavage with BrCN. It consisted of 238 amino acid residues and carbohydrate moiety attached to the 74th asparagine residue. The molecular weight of the protein moiety deduced from the sequence was 26,596. The locations of 10 half cystine residues are almost superimposable on those of RNase Rh from Rhizopus niveus and RNase T2 from Aspergillus oryzae which have similar base specificity. The homology between RNase M and RNase Rh and RNase T2 amounted to 97 and 160 amino acid residues, respectively. The amino acid sequences conserved in the three RNases are concentrated around the three histidine residues, which are supposed to form part of the active sites of these RNases.     

Expression of RNase Rh from Rhizopus niveus in yeast and characterization of the secreted proteins.

The full-length cDNA encoding RNase Rh, which is secreted extracellularly by Rhizopus niveus, was isolated and its nucleotide sequence was determined. It was placed under control of the promoter of the glyceraldehyde 3-phosphate dehydrogenase gene of Saccharomyces cerevisiae in a high expression vector in yeast. Since yeast cells transformed by this plasmid poorly secreted RNase into the medium, the plasmid pYE RNAP-Rh was constructed, in which the signal sequence of RNase Rh was replaced by the prepro-sequence of aspartic proteinase-I, one of the extracellular enzymes secreted by R. niveus. Yeast cells harboring pYE RNAP-Rh produced RNase efficiently (ca. 40 micrograms/ml) into the medium. The product was a mixture of six enzymes (RNase RNAP-Rhs) having 3, 5, 9, 13, 14, and 16 additional amino acid residues attached to the amino terminus of the mature RNase Rh. The major product was the RNase with three additional amino acids at the amino terminus. Limited digestion of RNase RNAP-Rhs with staphylococcal V8 protease succeeded in shortening the various lengths of extra amino acid residues attached to the amino terminus of RNase Rh, yielding an RNase that has 3 additional amino acids at the amino terminus. It has been named RNase RNAP-Rh. The RNase RNAP-Rh showed the same specific activity and CD spectra as those of RNase Rh, suggesting that the two have similar conformations to each other around aromatic amino acid residues and the peptide backbone.     

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 alpha-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.     

Crystal structure of a plant ribonuclease, RNase LE

Ribonuclease LE (RNase LE) from cultured tomato (Lycopersicon esculentum) cells is a member of the RNase T(2) family showing broad base specificity. The crystal structure of RNase LE has been determined at 1.65 A resolution. The structure consists of seven alpha-helices and seven beta-strands, belonging to an alpha+beta type structure. Comparison of the structure of RNase LE with that of RNase Rh, a microbial RNase belonging to the RNase T(2) family, reveals that while the overall folding topologies are similar to each other, major insertions and deletions are found at the N-terminal regions. The structural comparison, an amino acid sequence alignment of the RNase T(2) enzymes, and comparison of the disulfide-bonding pattern of these enzymes show that the structure of RNase LE shown here is the basic framework of the animal/plant subfamily of RNase T(2) enzymes (including a self-incompatibility protein called S-RNase), and the structure of RNase Rh is that of the fungal subfamily of RNase T(2) enzymes (including RNase T(2)). Subsequently, we superposed the active-site of the RNase LE with that of RNase Rh and found that (1) His39, Trp42, His92, Glu93, Lys96, and His97 of RNase LE coincided exactly with His46, Trp49, His104, Glu105, Lys108, and His109, respectively, of RNase Rh, and (2) two conserved water molecules were found at the putative P(1) sites of both enzymes. These facts suggest that plant RNase LE has a very similar hydrolysis mechanism to that of fungal RNase Rh, and almost all the RNase T(2) enzymes widely distributed in various species share a common catalytic mechanism. A cluster of hydrophobic residues was found on the active-site face of the RNase LE molecule and two large hydrophobic pockets exist. These hydrophobic pockets appear to be base binding sites mainly by hydrophobic interactions and are responsible for the base non-specificity of RNase LE.     

The complete amino acid sequence of ribonuclease from the seeds of bitter gourd (Momordica charantia)

The complete amino acid sequence of ribonuclease (RNase MC) from the seeds of bitter gourd (Momordica charantia) has been determined. This has been achieved by the sequence analysis of peptides derived by enzymatic digestion with trypsin, lysylendopeptidase, and chymotrypsin, as well as by chemical cleavage with cyanogen bromide. The protein contains 191 amino acid residues and has a calculated molecular mass of 21,259 Da. Comparison of this sequence with sequences of the fungal RNases, RNase T2, and RNase Rh, revealed that there are highly conserved residues at positions 32-38 (TXHGLWP) and 81-92 (FWXHEWXKHGTC). Furthermore, the sequence of RNase MC was found to be homologous to those of Nicotiana alata S-glycoproteins involved in self-incompatibility sharing 41% identical residues.     

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.     

Isolation, characterization, and primary structure of a base non-specific and adenylic acid preferential ribonuclease with higher specific activity from Trichoderma viride.

In order to elucidate the structure-function relationship of RNases belonging to the RNase T2 family (base non-specific and adenylic acid-preferential RNase), an RNase of this family was purified from Trichoderma viride (RNase Trv) to give three closely adjacent bands with RNase activity on slab-gel electrophoresis in a yield of 20%. The three RNases gave single band with the same mobility on slab-gel electrophoresis after endoglycosidase F digestion. The enzymatic properties including base specificity of RNase Trv were very similar to those of typical T2-family RNases such as RNase T2 from Aspergillus oryzae and RNase M from A. saitoi. The specific activity of RNase Trv towards yeast RNA was about 13-fold higher than that of RNase M. The complete primary structure of RNase Trv was determined by analyses of the peptides generated by digestion of reduced and carboxymethylated RNase Trv with Staphylococcus aureus V8 protease, lysylendopeptidase and alpha-chymotrypsin. The molecular weight of the protein moiety deduced from the sequence was 25,883. The locations of 10 half-cystine residues were almost superimposable upon those of other RNases of this family. The homologies between RNase Trv and RNase T2, RNase M, and RNase Rh (Rhizopus niveus) were 124, 132, and 92 residues, respectively. The sequences around three histidine residues, His52, His109, and His114, were highly conserved in these 4 RNases.     

The nucleotide and partial amino acid sequence of toxic shock syndrome toxin-1

The nucleotide sequence of toxic shock syndrome toxin-1 (TSST-1) has been determined. In addition, one-third of the predicted amino acid sequence was confirmed by amino acid sequence analysis of cyanogen bromide-generated TSST-1 protein fragments. The DNA sequencing results identified a 708-base pair open reading frame starting with an ATG, 7 base pairs downstream from a Shine-Dalgarno sequence, and terminating at a UAA stop codon. Amino acid analysis of the intact protein defined the NH2 terminus of the mature protein and located the cleavage point for the signal peptide (Ala/Ser). The signal peptide contained the first 40 amino acids and had characteristic structural similarities with other bacterial signal peptides. The coding sequence of the mature protein was 585 base pairs (194 amino acids) in length, and the molecular weight of the predicted protein was 22,049. This is in good agreement with the previously reported molecular weight of TSST-1 (22,000), as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. NH2-terminal amino acid sequence analysis performed on isolated TSST-1 CNBr fragments determined the position of the peptides in the TSST-1 sequence and verified the predicted amino acid sequence in those positions. Computer analyses of the amino acid sequence showed that TSST-1 has little or no sequence homology with biologically related toxins, streptococcal pyrogenic exotoxin A, and staphylococcal enterotoxins B and C.     

Expression of bovine pancreatic ribonuclease A coded by a synthetic gene in Bacillus subtilis

Two different hybrid genes were constructed which fuse the Bacillus amyloliquefaciens alkaline protease gene (apr[BamP]) promoter and signal peptide coding region to a synthetic bpr gene coding for the mature bovine pancreatic RNase A. The first gene fusion (apr-bpr1) contained the apr[BamP] signal peptide coding region fused to mature bpr through a linker coded 3-amino acid region and retained the signal processing site ala-ala of the alkaline protease. The second fusion (apr-bpr2) joined the end of the apr[BamP] signal peptide coding sequence to the mature bpr resulting in a hybrid signal processing site ala-lys. B. subtilis strains harboring these gene fusions secreted bovine pancreatic RNase A into the growth medium. Cleavage at the hybrid signal processing site ala-lys resulted in the secretion of bovine pancreatic RNase A from B. subtilis which had an N-terminal amino acid sequence that was identical to the native RNase A. Bovine pancreatic RNase A contains four disulfide bonds and the proper formation of these bonds is required for activity. RNase activity could be detected in the culture supernatants of strains carrying the apr-bpr gene fusions, which suggests that the proper disulfide bonds have formed spontaneously.     

On a salmon (Oncorhynchus [corrected] keta) liver RNase, belonging to RNase T2 family: primary structure and some properties

A base-nonspecific and acid ribonuclease (RNase Ok2) was purified from the liver of a salmon (Oncorhnchus keta) to a homogeneous state by SDS-PAGE. The primary structure of RNase Ok2 was determined by protein chemistry and molecular cloning. The RNase Ok2 was a glycoprotein and consisted of 216 amino acid residues. Its molecular mass of protein moiety was 25,198, and its amino acid sequence showed that it belongs to the RNase T2 family of enzymes. The optimal pH of RNase Ok2 was around 5.5. The base preferences at the B1 and B2 sites were estimated from the rates of hydrolysis of 16 dinucleoside phosphates to be G>A>U, C, and G>A>U>C respectively. In this enzyme, one of the three histidine residues which have been thought to be important for catalysis of RNase Rh, a typical RNase of this family of enzymes, His104 was replaced by tyrosine residue. Based on the results, the role of H104, which has been proposed to be a phosphate binding site with a substrate, was reconsidered, and we proposed a revised role of this His residue in the hydrolysis mechanism of RNase T2 family enzymes.     

The three-dimensional structure and X-ray sequence reveal that trichomaglin is a novel S-like ribonuclease

Trichomaglin is a protein isolated from root tuber of the plant Maganlin (Trichosanthes Lepiniate, Cucurbitaceae). The crystal structure of trichomaglin has been determined by multiple-isomorphous replacement and refined at 2.2 A resolution. The X-ray sequence was established, based on electron density combined with the experimentally determined N-terminal sequence, and the sequence information derived from mass spectroscopic analysis. X-ray sequence-based homolog search and the three-dimensional structure reveal that trichomaglin is a novel S-like RNase, which was confirmed by biological assay. Trichomaglin molecule contains an additional beta sheet in the HV(b) region, compared with the known plant RNase structures. Fourteen cystein residues form seven disulfide bridges, more than those in the other known structures of S- and S-like RNases. His43 and His105 are expected to be the catalytic acid and base, respectively. Four hydrosulfate ions are bound in the active site pocket, three of them mimicking the substrate binding sites.     

Crystal structure of a ribonuclease from the seeds of bitter gourd (Momordica charantia) at 1.75 A resolution.

The ribonuclease MC1 (RNase MC1) from seeds of bitter gourd (Momordica charantia) consists of 190 amino acid residues with four disulfide bridges and belongs to the RNase T(2) family, including fungal RNases typified by RNase Rh from Rhizopus niveus and RNase T(2) from Aspergillus oryzae. The crystal structure of RNase MC1 has been determined at 1.75 A resolution with an R-factor of 19.7% using the single isomorphous replacement method. RNase MC1 structurally belongs to the (alpha+beta) class of proteins, having ten helices (six alpha-helices and four 3(10)-helices) and eight beta-strands. When the structures of RNase MC1 and RNase Rh are superposed, the close agreement between the alpha-carbon positions for the total structure is obvious: the root mean square deviations calculated only for structurally related 151 alpha-carbon atoms of RNase MC1 and RNase Rh molecules was 1.76 A. Furthermore, the conformation of the catalytic residues His-46, Glu-105, and His-109 in RNase Rh can be easily superposed with that of the possible catalytic residues His-34, Glu-84, and His-88 in RNase MC1. This observation strongly indicates that RNase MC1 from a plant origin catalyzes RNA degradation in a similar manner as fungal RNases.     

Modification of a ribonuclease from Rhizopus sp. with 1-cyclohexyl-3-(2-morpholinyl-(4)-ethyl)carbodiimide p-toluenesulfonate

The carboxyl group in a ribonuclease from Rhizopus sp. (RNase Rh) was modified by a water-soluble carbodiimide, 1-cyclohexyl-3-(2-morpholinyl-(4)-ethyl)carbodiimide p-toluenesulfonate (CMC). From the relation between the extent of modification and the enzymatic activity, it was concluded that at least the modification of two carboxyl groups seemed to induce the loss in enzymatic activity. In the presence of 1 M cytidine, RNase Rh activity was protected from the CMC-modification. Under conditions in which the enzyme was inactivated to 20% activity, about 70% of the enzymatic activity was retained in the presence of cytidine. The inactivation of the RNase Rh pre-treated with CMC in the presence of cytidine with [14C]CMC indicated that the RNase Rh lost its enzymatic activity with the incorporation of about one [14C]CMC. Therefore, it could be concluded that one carboxyl group is involved in the active site of RNase Rh. The binding of the CMC-modified RNase Rh with 2'-AMP was studied spectrophotometrically. The affinity of the modified RNase Rh towards 2'-AMP decreased markedly upon CMC modification.     

The RNase PD2 gene of almond (Prunus dulcis) represents an evolutionarily distinct class of S-like RNase genes

A cDNA for an S-like RNase (RNase PD2) has been isolated from a pistil cDNA library of Prunus dulcis cv. Ferragnés. The cDNA encodes an acidic protein of 226 amino acid residues with a molecular weight of 25 kDa. A potential N-glycosylation site is present at the N-terminus in RNase PD2. A signal peptide of 23 amino acid residues and a transmembrane domain are predicted. The two active-site histidines present in enzymes of the T2/S RNase superfamily were detected in RNase PD2. Its amino acid sequence shows 71.2% similarity to RNS1 of Arabidopsis and RNase T2 of chickpea, respectively. Northern blotting and RT-PCR analyses indicate that PD2 is expressed predominantly in petals, pistils of open flowers and leaves of the almond tree. Analyses of shoots cultured in vitro suggested that the expression of RNase PD2 is associated with phosphate starvation. Southern analysis detected two sequences related to RNase PD2 in the P. dulcis genome. RFLP analysis showed that S-like RNase genes are polymorphic in different almond cultivars. The PD2 gene sequence was amplified by PCR and two introns were shown to interrupt the coding region. Based on sequence analysis, we have defined three classes of S-like RNase genes, with the PD2 RNase gene representing a distinct class. The significance of the structural divergence of S-like RNase genes is further discussed. Received: 24 January 2000 / Accepted: 17 March 2000     

The amino acid sequence of ribonuclease U1, a guanine-specific ribonuclease from the fungus Ustilago sphaerogena

The complete amino acid sequence of ribonuclease U1 (RNase U1), a guanine-specific ribonuclease from a fungus, Ustilago sphaerogena, was determined by conventional protein sequencing, using peptide fragments obtained by several enzymatic cleavages of the performic acid-oxidized protein. The oxidized protein was first cleaved by trypsin and the resulting peptides were purified and their amino acid sequences were determined. These tryptic peptides were aligned with the aid of overlapping peptides isolated from a chymotryptic digest of the oxidized protein. The amino acid sequence thus deduced was further confirmed by isolation and analysis of peptides obtained by digestion of the oxidized protein with lysyl endopeptidase. The location of the disulfide bonds was deduced by isolation and analysis of cystine-containing peptides from a chymotryptic digest of heat-denatured RNase U1. These results showed that the protein is composed of a single polypeptide chain of 105 amino acid residues cross-linked by two disulfide bonds, having a molecular weight of 11,235, and that the NH2-terminus is blocked by a pyroglutamate residue. It has an overall homology with other guanine-specific or related ribonucleases, and shows 48% identity with RNase T1 and 38% identity with RNase U2.     

Entire nucleotide sequence of the pullulanase gene of Klebsiella aerogenes W70.

We determined the entire nucleotide sequence of the Klebsiella aerogenes W70 pullulanase gene (pulA) contained on a 4.2-kilobase-pair fragment of plasmid pPB174. The amino acid composition deduced from an open reading frame of 3,288 base pairs agreed closely with that determined for the intracellular pullalanase. The precursor enzyme consisted of 1,096 amino acid residues and contained a hydrophobic N-terminal signal peptide and the consensus sequence for the bacterial prelipoprotein signal peptide cleavage site.     

The amino acid sequence of ribonuclease N1, a guanine-specific ribonuclease from the fungus Neurospora crassa

The complete amino acid sequence of ribonuclease N1 (RNase N1), a guanine-specific ribonuclease from a fungus, Neurospora crassa, was determined by conventional protein sequencing, using peptide fragments obtained by tryptic digestion of cyanogen bromide-treated RNase N1 and by Staphylococcus aureus V8 protease digestion of heat-denatured RNase N1. The results showed that the protein is composed of a single polypeptide chain of 104 amino acid residues cross-linked by two disulfide bonds and has a molecular weight of 11,174: (sequence; see text) (Disulfide bonds: C2-C10, C6-C103) The amino acid sequence was homologous with those of RNase T1 (65% identity) and related microbial RNases.     

Crystal and molecular structure of RNase Rh, a new class of microbial ribonuclease from Rhizopus niveus.

The crystal structure of RNase Rh, a new class of microbial ribonuclease from Rhizopus niveus, has been determined at 2.5 A resolution by the multiple isomorphous replacement method. The crystal structure was refined by simulated annealing with molecular dynamics. The current crystallographic R-factor is 0.200 in the 10-2.5 A resolution range. The molecular structure which is completely different from the known structures of RNase A and RNase T1 consists of six alpha-helices and seven beta-strands, belonging to the alpha+beta type structure. Two histidine and one glutamic acid residues which were predicted as the most probably functional residues by chemical modification studies are found to be clustered. The steric nature of the active site taken together with the relevant site-directed mutagenesis experiments (Irie et al.) indicates that: (i) the two histidine residues are the general acid and base; and (ii) an aspartic acid residue plays a role of recognizing adenine moiety of the substrate.     

Base Specificity and Primary Structure of Poly U-preferential Ribonuclease from Chicken Liver

The primary structure and base specificity of chicken liver RNase CL₁ which has been reported by Miura et al. [Chem. Pharm. Bull., 32,4053–4060 (1984)] as poly U-preferential RNase, were extensively studied. The sequence study of this enzyme and comparison of the amino acid sequence of the enzyme with homologous RNases from oyster and Drosophila melanogaster suggested that RNase CL₁ consists of three peptides with 17, 19, and 163 amino acid residues. The amino acid sequence of these three peptides were identified. The two small peptides are joined to the large peptide by disulfide bridges. The amino acid sequence of RNase CL₁ had 62 (31.2%) and 63 residues (31.6%) identical with oyster RNase and D. melanogaster RNase, respectively, and belongs to the RNase T₂ family RNase.

Reassessment of the base specificity of RNase CL₁ found that it is guanylic acid, then uridylic acid-preferential, and not poly U preferential.