Purification and properties of a ribonuclease from corn leaf tissues

An acid endoribonuclease isolated from corn leaf tissues was purified 530 times. Gel electrophoresis indicated that the enzyme was homogeneous. The enzyme showed an optimum pH at 5.5 and an apparent molecular weight of 32 000. Corn RNase attacks natural RNAs and synthetic polyribonucleotides and the relative rate of degradation was poly U > yeast RNA > E. coli tRNA > poly A ⪢ poly C. Zn²⁺, Mg²⁺, Mn²⁺ and EDTA inhibited the enzyme activity. No stimulation by K⁺ was observed. Cu²⁺ and heparin had no effect on the activity. The results suggest that the investigated RNase differs from other known corn ribonucleases.     

Kinetic and product distribution analysis of human eosinophil cationic protein indicates a subsite arrangement that favors exonuclease-type activity.

With the use of a high yield prokaryotic expression system, large amounts of human eosinophil cationic protein (ECP) have been obtained. This has allowed a thorough kinetic study of the ribonuclease activity of this protein. The catalytic efficiencies for oligouridylic acids of the type (Up)nU>p, mononucleotides U>p and C>p, and dinucleoside monophosphates CpA, UpA, and UpG have been interpreted by the specific subsites distribution in ECP. The distribution of products derived from digestion of high molecular mass substrates, such as poly(U) and poly(C), by ECP was compared with that of RNase A. The characteristic cleavage pattern of polynucleotides by ECP suggests that an exonuclease-like mechanism is predominantly favored in comparison to the endonuclease catalytic mechanism of RNase A. Comparative molecular modeling with bovine pancreatic RNase A-substrate analog crystal complexes revealed important differences in the subsite structure, whereas the secondary phosphate-binding site (p2) is lacking, the secondary base subsite (B2) is severely impaired, and there are new interactions at the po, Bo, and p-1 sites, located upstream of the P-O-5' cleavable phosphodiester bond, that are not found in RNase A. The differences in the multisubsites structure could explain the reduced catalytic efficiency of ECP and the shift from an endonuclease to an exonuclease-type mechanism.     

A covalent angiogenin/ribonuclease hybrid with a fourth disulfide bond generated by regional mutagenesis

Human angiogenin is a blood vessel inducing protein whose primary structure displays 33% identity to that of bovine pancreatic ribonuclease A (RNase A). Angiogenin catalyzes limited cleavage of 18S and 28S ribosomal RNA and is several orders of magnitude less potent than RNase A toward conventional substrates. A striking structural difference between angiogenin and RNase is the virtual absence of sequence similarity within the region of RNase that contains the Cys-65--Cys-72 disulfide bond. Indeed, angiogenin lacks this disulfide linkage. The present report describes the use of regional mutagenesis to generate a covalent angiogenin/RNase hybrid protein, ARH-I, where residues 58-70 of angiogenin have been replaced by the corresponding segment of RNase A (residues 59-73). The protein expressed in Escherichia coli readily folds at pH 8.5 to form the four expected disulfide bonds. The in vivo angiogenic potency of ARH-I is markedly diminished compared with that of angiogenin when examined using the chick chorioallantoic membrane assay. In contrast, its enzymatic activity is dramatically increased. With high molecular weight wheat germ RNA and tRNA, ARH-I is 660- and 300-fold more active than angiogenin, respectively, while with poly(uridylic acid), poly(cytidylic acid), cytidylyl(3'----5')adenosine (CpA), and uridylyl(3'----5')adenosine (UpA) activity is enhanced by about 200-fold. In addition, the specificity of ARH-I toward dinucleoside 3',5'-phosphates is qualitatively similar to RNase A; while angiogenin prefers cytidylyl(3'----5')guanosine (CpG) to UpA, both RNase and the hybrid prefer UpA to CpG. ARH-I also displays greater than 10-fold enhanced activity toward rRNA in intact ribosomes, while abolishing the capacity of the ribosome to support cell-free protein synthesis. The enhanced enzymatic properties of ARH-I parallel a 2-fold increase in chemical reactivity of active-site lysine and histidine residues based on rates of chemical modification. The data indicate that introduction of a region of RNase A containing the Cys-65--Cys-72 disulfide bond into angiogenin dramatically increases RNase-like enzymatic activity while reducing its angiogenicity.     

First demonstration of lactoribonuclease, a ribonuclease from bovine milk with similarity to bovine pancreatic ribonuclease

The isolation of a ribonuclease designated lactoribonuclease, with a molecular weight and an N-terminal amino acid sequence identical to those of bovine pancreatic ribonuclease, was first reported from bovine milk. After removal of globulin from acid whey by precipitation with 1.8 M (NH4)2SO4, (NH4)2SO4 was added to attain a concentration of 3.6 M. Adsorption on the ion exchanger CM-Sepharose and subsequently on Mono S by fast protein liquid chromatography yielded pure lactoribonuclease. The enzyme, like pancreatic ribonuclease, was most active at pH 7.5 with yeast transfer RNA (tRNA) as substrate. Lactoribonuclease and pancreatic ribonuclease showed a strong preference for poly(C) over poly(U). However, pancreatic ribonuclease did so with a higher specific activity, suggesting that the two ribonucleases are not identical. No inhibitory effect was shown by either lactoribonuclease or pancreatic ribonuclease toward poly (A) and poly (G). The effect of lactoribonuclease and pancreatic ribonuclease on tRNA increased with the concentration of tRNA. Lactoribonuclease inhibited cell-free translation in a rabbit reticulocyte lysate system with an IC50 of 3.5 nM while the corresponding IC50 for pancreatic ribonuclease was 0.09 nM.     

Purification and characterization of a new ribonuclease from fruiting bodies of the oyster mushroom Pleurotus ostreatus.

A ribonuclease (RNase), possessing an N-terminal sequence disparate from those of ribonucleases from other mushrooms and previously isolated Pleuotus ostreatus RNases, was purified from the fruiting bodies of the edible mushroom Pleurotus ostreatus. The N-terminal sequence of Pleurotus ostreatus RNase did not manifest homology even to a previously reported RNase from the same mushroom. The ribonuclease was adsorbed on CM-Sepharose and Mono S. It exhibited a molecular mass of 12 kDa in both sodium dodecyl sulphate-polyacrylamide gel electrophoresis and gel filtration on Superdex 75. The ribonuclease displayed an activity of 11490 U/mg on yeast tRNA. The highest ribonuclease activity was exhibited toward poly U, followed by poly A and poly C. No activity was shown toward poly G. The optimal pH for its activity was 7 and the optimal temperature was 55 degrees C. It inhibited cell-free translation in a rabbit reticulocyte lysate with an IC50 of 240 nM.     

On the accessibility and selection of the initiator site of mRNA in protein synthesis

The specificity of the cell-free system of Escherichia coli for mRNA was examined, and the “accessibility” of some natural and synthetic RNAs to the ribosomes was determined by measurement of AcPhe-tRNA and fMet-tRNA binding, AcPhe-puromycin and fMet-puromycin formation, and polypeptide synthesis. The E. coli system effectively initiates the translation of various synthetic RNAs with AcPhe-tRNA or fMet-tRNA under conditions optimal for the translation of viral RNA. Poly(A,G,U) is accessible to the ribosomes according to all of the above criteria. Poly(A,C,G,U), 23 S rRNA, R17 RNA, and MS2 RNA, on the other hand, show limited accessibility when tested for initiator tRNA binding, or for AcPhe-puromycin and fMet-puromycin formation. MS2 and R17 RNA, but not poly(A,C,G,U) and 23 S rRNA, show accessibility when measured by polypeptide synthesis. The results suggest that, except at initiator sites of natural mRNA, an RNA containing about equal amounts of all four bases is inaccessible to E. coli ribosomes for polypeptide synthesis. Rate constants obtained for fMet-tRNA binding with MS2 RNA, poly(A,G,U), and poly(C,G,U) indicate that the ribosomes do not have any special affinity for the viral RNA. Thus, the selection of the initiator site in protein synthesis may be critically determined more by the accessibility of the initiator codon than by ribosomal recognition of the site.     

Interaction between non-formylated initiator Met-tRNA(fMet) and the ribosomal A-site from Escherichia coli

We report studies in vitro of the interaction between non-formylated initiator Met-tRNA(fMet) and 70S ribosomes. The binding of Met-tRNA(fMet) to ribosomes carrying fMet-tRNA(fMet) in the P-site is strongly stimulated by elongation factor EF-Tu:GTP in the presence of (AUG)3. The enzymatically bound Met-tRNA(fMet) does not react with puromycin. The bound Met-tRNA(fMet) can accept formylmethionine from P-site-bound fMet-tRNA(fMet). These results demonstrate a functionally active binding at the ribosomal A-site. Partial ribonuclease digestion (footprinting) was used to study the sites in Met-tRNA(fMet) which are involved in the interaction with the ribosomal A-site. The results show that a large part of the tRNA molecule is protected by the ribosome against ribonuclease digestion. In addition to the protection found in the amino acid region and the anticodon arm, protection is seen in the D-loop and in the extra arm. No region within the bound tRNA is found to be more accessible for RNases than in the free Met-tRNA(fMet). The reported enhancement of ribonuclease cuts in the D- and T-arms of A-site-bound Phe-tRNAPhe is thus not found in A-site bound Met-tRNA(fMet).     

Purification from normal human plasma and biochemical characterization of a ribonuclease specific for poly(C) and poly(U)

A new specific ribonuclease from normal human plasma has been purified to homogeneity, following a five-step purification protocol that included DEAE-Sepharose, CM-Sepharose, and Heparin-Sepharose chromatographies. The purified enzyme was found to be glycosylated and appeared as a single 25-kDa band on a SDS polyacrylamide gel. This RNase is poly(C) preferential, degrading poly(U) at a lower rate. Activity of this RNase toward cleavage of native substrates such as ribosomal RNA was also detected. The human plasma ribonuclease is a thermolabile molecule, exhibiting maximum activity at pH 6.5. Comparison between other known plasma RNases and the human plasma ribonuclease described here indicated a variety of differences in their biochemical and catalytic properties.     

Purification and characterization of a novel UpN-specific endoribonuclease VI from Artemia larvae

Artemia larval ribonuclease (Sebastián, J., and Heredia, C. F., (1978) Eur. J. Bichem. 90, 405-411) has been purified near homogeneity and its properties were studied. It consists of a single polypeptide chain of 38,000 daltons. It requires a divalent cation for activity. Ca2+ is the most effective among the metals tested. The metal dependence of the activity is biphasic. Maximal activity is obtained at 5-10 mM. In the absence of metals and chelating agents in the assay, 30-40% of the activity is observed. However, if chelating agents are added, the activity is abolished. At low concentrations of free metal (1-20 microM), 30-40% of maximal activity is obtained with Ca2+ or Mn2+, but not with Mg2+, Ca2+, but not Mn2+ or Mg2+, protects the enzyme from thermal inactivation. The best substrates for Artemia ribonuclease are poly(U) and poly(A), although with the latter it has only 10% the activity shown with the former. Using poly(U) as substrate, the products of a terminal digestion are P-2':3'-Urd and 3'-UMP. Using dinucleoside monophosphates as substrates, the enzyme is highly specific for a U residue at the 3' side of the phosphodiester bond (UpN), especially UpA, being inactive if the U residue is at the 5' side (NpU). Although some of its properties are similar to other eukaryotic or prokaryotic ribonucleases, its high specificity for UpN bonds suggest that this is a new type of ribonuclease. Moreover, it is a potentially useful enzyme for RNA analysis and/or sequencing.     

Purification of an alkaline ribonuclease from soluble fraction of beef brain.

A ribonuclease (ribonucleate 3-pyrimidine-oligonucleotidohydrolase, EC 3.1.4.22) was purified 8300-fold from soluble fraction of beef brain and its properties were investigated. The enzyme is an endonuclease capable of hydrolyzing tRNA, rRNA, poly(C), but shows no activity towards poly(U), poly(A), and poly(G). The preparation is free of deoxyribonuclease, non-specific phosphodiesterase and phosphomonoesterase activity. The enzyme has a pH optimum of 7.6, is not heat stable, has a molecular weight of 25 000, and has a K-m of 134 mu rRNA and K-m of 1600 mug poly(C) per ml.     

A ribonuclease from yeast associated with the 40 S ribosomal subunit.

1. Autodegradation of yeast ribosomes is due to a 'latent' ribonuclease which is associated with the 40 S ribosomal subunit. 2. The ribonuclease was extracted in the presence of EDTA from ribosomes and purified 118-rold by protamine sulphate precipitation, (NH4)2SO4 fractionation and chromatography on DEAE-cellulose. 3. The optimum pH for this enzyme is 5 to 6.5 while the optimum temperature is 45 to 50 degrees C. Incubation for 10 min at 60 degrees C caused a reduction in enzyme activity of 70%. 4. The ribonuclease has an endonucleolytic activity against rRNA, tRNA, poly(A), poly(U) and poly(C) but does not degrade poly(G) or DNA. It hydrolyzes the homopolymers to nucleoside 3'-phosphates. 5. Zn2+, Mn2+, heparin, glutathione and p-chloromercuribenzoate inhibit the ribonuclease, while Na+, K+, EDTA and sermidine have only little or no effect. 6. It binds tightly to yeast ribosomes but only loosely to ribonuclease-free wheat germ ribosomes. 7. Polyribosomes possess less autodegradation activity than monoribosomes, isolated from the same homogenate.     

Demonstration of the "5-8 S" ribosomal sequence in HeLa cell ribosomal precursor RNA

HeLa cell “5.8 S” ribosomal RNA was digested with T₁ ribonuclease and the digestion products were characterized. In particular several hexa-, or larger, oligonucleotides were well fractionated by T₁ ribonuclease plus alkaline phosphatase fingerprints. The sequences of these large products were determined. The same large products were identified in fingerprints of “native” 28 S RNA, that is, 28 S RNA to which 5.8 S RNA is attached. The products were demonstrably absent in fingerprints of heat-denatured 28 S RNA, which lacks the 5.8 S fragment. The oligonucleotides were present in fingerprints of 32 S RNA, whether previously heated or not. One of the largest 5.8 S oligonucleotides contains an alkali-stable (2′-O-methylated) dinucleotide, Gm-C. This product was identified in fingerprints of methyl-labelled 45 S RNA. These findings prove that the 5.8 S ribosomal sequence is present within HeLa cell ribosomal precursor RNA. In addition to the methylated nucleotide, two pseudouridylate residues were discovered in HeLa cell 5.8 S RNA.     

Chemical synthesis of diastereomeric diadenosine boranophosphates (ApbA) from 2'-O-(2-cyanoethoxymethyl)adenosine by the boranophosphotriester method

We have synthesized diastereomerically pure diadenosine 3',5'-boranophosphates (Ap(b)A) by using the boranophosphotriester method from ribonucleosides protected with the 2'-hydroxy protecting group 2-cyanoethoxymethyl (CEM). Melting curves of the triple-helical complex of the dimer Ap(b)A and 2poly(U) at high ionic strength revealed that presumptive (Sp)-Ap(b)A had a much higher affinity and presumptive (Rp)-Ap(b)A a much lower affinity for poly(U) than the natural dimer ApA did. In contrast, the affinities of these dimers for poly(dT) were similar. Both the (Rp)- and the (Sp)-boranophosphate diastereomers showed much higher resistance to digestion by snake venom phosphodiesterase and nuclease P1 than ApA did. They have potential for use as synthons to be incorporated into boranophosphate oligonucleotides. In particular, because oligonucleotides containing Sp boranophosphate nucleotides are expected to bind more strongly and specifically to RNA than natural oligoribonucleotides do, they may find application in the isolation and detection of functional RNA in basic research and diagnostics.     

Interaction of ribo- and deoxyriboanalogs of yeast tRNA(Phe) anticodon arm with programmed small ribosomal subunits of Escherichia coli and rabbit liver.

A synthetic ribooligonucleotide, r(CCAGACUGm-AAGAUCUGG), corresponding to the unmodified yeast tRNA(Phe) anticodon arm is shown to bind to poly(U) programmed small ribosomal subunits of both E. coli and rabbit liver with affinity two order less than that of a natural anticodon arm. Its deoxyriboanalogs d(CCAGACTGAAGATCTGG) and d(CCAGA)r(CUGm-AAGA)d(TCTGG), are used to study the influence of sugar-phosphate modification on the interaction of tRNA with programmed small ribosomal subunits. The deoxyribooligonucleotide is shown to adopt a hairpin structure. Nevertheless, as well as oligonucleotide with deoxyriboses in stem region, it is not able to bind to 30S or 40S ribosomal subunits in the presence of ribo-(poly(U] or deoxyribo-(poly (dT) template. The deoxyribooligonucleotide also has no inhibitory effect on tRNA(Phe) binding to 30S ribosomes at 10-fold excess over tRNA. Neomycin does not influence binding of tRNA anticodon arm analogs used. Complete tRNA molecule and natural modifications of anticodon arm are considered to stabilize the arm structure needed for its interaction with a programmed ribosome.     

Self-cleavage of p2Sp1 RNA with Mg2+ and non-ionic detergent (Brij 58)

The precursor of an RNA molecule from T4-infected E. coli cells (p2Sp1 RNA) has the capacity to cleave itself at specific positions [(UpA (139-140) and CpA (170-171)], within a putative loop and stem structure. This sequence-specific cleavage requires at least a monovalent cation and non-ionic detergents. We studied the self-cleavage reaction of an RNA fragment (GUUUCGUACAAAC) (R1) with the sequence corresponding to the p2Sp1 RNA in the presence of Mg2+ and non-ionic detergents. It requires Mg2+ and is aided by a non-ionic detergent, Brij 58. The cleavage reaction is time, temperature, and pH-dependent. The cleavage occurs at the phosphodiester bond between UpA and CpA on the RNA fragment (GUUUCGUACAAAC) (R1). Furthermore, the maximum of cleavage of R1 occurs at a very low Mg2+ concentration (< or = 5 mM).     

A proton magnetic resonance study of the interaction of adenylyl (3' is greater than 5') adenosine with polyuridylic acid

The interaction of adenylyl (3′ → 5′) adenosine (ApA) with polyuridylic acid in D₂O solution at neutral pD has been studied by high resolution proton magnetic, resonance spectroscopy. At temperatures above ～32°C, no evidence was obtained for the interaction of ApA with poly U. Below this temperature, a rigid triple-stranded complex involving a stoichiometry of 1 adenine to 2 uracil bases is formed, presumably via specific adenine–uracil base-pairing and cooperative base stacking of the adenine bases in a manner similar to that previously reported for the adenosine–poly U complex.     

A simple method for electrophoretic selection and fractionation of poly(A)-containing RNA and poly(A).

A simple procedure, useful for quantitative and qualitative assays of poly(A)-containing RNA and poly(A), as well as for preparative purposes, is described. Glass-fiber filters with immobilized poly(U), a well-known technique for absorption of poly(A)-containing RNA, is combined with electrophoresis in a gel slab of agarose. In front of each of the two troughs in a gel slab, glass-fiber filters are inserted, one of which is impregnated with poly(U). Two identical RNA samples, e.g., split samples of total RNA from salivary glands of Chironomus tentans, are applied to the troughs and are moved electrophoretically across two different filters. The electrophoresis is conducted under conditions which promote the formation of duplexes between absorbed poly(U) and moving poly(A). While the passage of RNA chains across the control filter may take place essentially freely, RNA molecules that contain poly(A) hybridize with poly(U) fixed in the glass-fiber filter and become trapped there. The difference between resulting gel profiles [pattern of the total RNA minus the pattern of RNA not containing poly(A)] yields the electrophoretic distribution of poly(A)-containing RNA. In addition, poly(A)-containing RNA can be eluted from the poly(U) filter with formamide and subjected to electrophoresis without a subsequent precipitation in ethanol. No measurable quantities of ribosomal RNA or tRNA are retained on the poly(U) glass-fiber filters. The hybridization technique enables a quantitative retention of poly(A) molecules representing a wide range of chain lengths.     

Effect of non-complementary nucleotides on the rate of helix formation: kinetics of formation of poly (I)-poly (C,I) and poly (I)-poly (C,U) complexes

Apparent second-order rate constants for complex formation between poly (I) and poly (C) and copolymers of C containing non-complementary I or U residues have been determined spectrophotometrically. The rate constants decrease as the concentration of either I or U in the C strands increases–the effect seems insensitive to the species of residue involved, when differences in the thermal stabilities of the poly (I) poly (C,I) and poly (I). poly (C,U) complexes are taken into account. These results suggest that low concentrations of relatively stable defects can alter the apparent kinetic “complexity” of polynucleotides as determined by hybridization methods (C₀t analysis).     

Synthesis and characterization of fluorescent dinucleotide substrate for the DNA-dependent RNA polymerase from Escherichia coli

New fluorescent derivatives of dinucleoside monophosphates, (5'-AmNS)UpA/ApU/GpU/CpA, with a fluorophore, 1-aminonaphthalene-5-sulfonic acid (AmNS), attached to the first nucleotide of the dinucleoside monophosphates via a 5'-secondary amine linkage were synthesized in good yield. The chemical structure of (5'-AmNS)ApU was proved by the phosphodiesterase digestion followed by Whatman No. 3MM paper chromatographic and spectroscopic analysis of the digested products. The ability of these analogs to be incorporated into the 5' terminus of RNA chain forming fluorescent oligonucleotides by Escherichia coli RNA polymerase was studied in the presence of a synthetic DNA template. The enzymatic reaction of (5'-AmNS)UpA and [3H]UTP in the presence of poly(dA-dT) yielded (5'-AmNS)UpAp[3H]U in greater than 30% yield with the Km values of 5 and 2.5 microM and Vmax values of 17 and 25 nmol/min/mg of enzyme for (5'-AmNS)UpA and UpA, respectively. The structure of this fluorescent trinucleotide was identified by RNase A digestion and paper chromatographic analysis of the digested products. (5'-AmNS)UpA or (5'-AmNS)ApU exhibits two absorption maxima around 270 and 340-350 nm and a fluorescent emission maximum at 445 nm when excited at 340 nm. These spectral characteristics permit their use as energy donors for the transfer of energy to the intrinsic cobalt of the cobalt-substituted RNA polymerases. Upon hydrolysis of the phosphodiester bond of these analogs by venom phosphodiesterase, the absorption at 340 and 270 nm increased by 5 and 20%, respectively, while their fluorescence at 445 nm was enhanced by 25%. Thus, these analogs can be used for studying the dynamics of initiation and elongation reactions catalyzed by DNA-dependent RNA polymerases by absorption and fluorescence spectroscopies.