The Complexing of Lysozyme with Poly C and Other homopolymers

Lysozyme forms very large complexes with poly C, in acetate buffer solutions (pH 5.4), when the ratio of lysozyme to poly C concentration is 3/2. When this is less than 3/8 there is virtually no complexing, as evidenced by the low light-scattering power of such mixtures. At such relatively high poly C concentrations, the addition of pancreatic ribonuclease causes both the intensity and dissymmetry of scattering to rise to very high values after which time the intensity falls exponentially with time and with very little change in dissymmetry. Other homopolymers also form largest complexes with lysozyme at characteristic concentration ratios.     

Protein-polynucleotide scattering centers as a protein structure probe

When certain basic globular proteins are mixed with nucleic acids near a critical concentration ratio, large, low density scattering centers of about 10⁹ particle weight are created. Scattering from these complexes is altered when thermally inactivated proteins are substituted for enzymes in their native, globular conformation. Scattering data from heat-treated ribonuclease and lysozyme mixed with four different synthetic homopolyribonucleotides are reported. The concentration of nucleic acid necessary to produce maximum scattering from a heat-treated protein sample is shown to be a direct indication of the amount of enzyme that remains biologically active after being heated.     

Protein-polynucleotide scattering centers as a protein structure probe.

When certain basic globular proteins are mixed with nucleic acids near a critical concentration ratio, large, low density scattering centers of about 10(9) particle weight are created. Scattering from these complexes is altered when thermally inactivated proteins are substituted for enzymes in their native, globular conformation. Scattering data from heat-treated ribonuclease and lysozyme mixed with four different synthetic homopolyribonucleotides are reported. The concentration of nucleic acid necessary to produce maximum scattering from a heat-treated protein sample is shown to be a direct indication of the amount of enzyme that remains biologically active after being heated.     

Polynucleotide sequences in eukaryotic DNA and RNA that form ribonuclease-resistant complexes with polyuridylic acid

When annealed with synthetic polynucleotides and treated with ribonuclease under appropriate conditions, poly(U) forms the ribonuclease-resistant complexes poly(rA) · poly(U) (1:1), poly(dA) · 2poly(U) (1:2) and poly · (dA)poly(dT) · poly(U) (1:1:1). This forms the basis of a quantitative assay of poly(rA), poly(dA) and poly(dA) · poly(dT) sequences in unlabelled nucleic acids. Using this assay, duck haemoglobin messenger RNA is shown to contain a poly(rA) sequence approximately 100 nucleotides long.Eukaryotic DNAs contain small amounts of sequences that react with poly(U). In the case of duck DNA, these sequences are considerably shorter than the mRNA-associated sequences and are interspersed widely with other sequences. It is concluded that if duck DNA does contain poly(dA) sequences corresponding to mRNA-associated poly(rA) sequences, there are fewer than 8000 of these per haploid genome.     

A ribonuclease from Chinese ginseng (Panax ginseng) flowers

A ribonuclease, with a molecular mass of 23kDa, and much higher activity toward poly(U) than poly(C) and only negligible activity toward poly(A) and poly(G), was isolated from the aqueous extract of Chinese ginseng (Panax ginseng) flowers. The ribonuclease was unadsorbed on diethylaminoethyl-cellulose and adsorbed on Affi-gel blue gel and carboxymethyl-cellulose. High activity of the ribonuclease was maintained at pH 6-7. On either side of this pH range, there was a precipitous drop in enzyme activity. The activity of the enzyme peaked at 50 degrees C and fell to about 20% of the maximal activity when the temperature was lowered to 20 degrees C or raised to 80 degrees C. The characteristics of this ribonuclease were different from those of ribonuclease previously purified from ginseng roots.     

Interaction of trivaline with single-stranded polyribonucleotides]

Binding of tripeptide H-Val3-(NH)2-Dns (TVP) to polyribonucleotides was studied by fluorescence methods, circular and flow linear dichroism, equilibrium dialysis and electron microscopy. It was found that TVP binds to poly(U) in monomer, dimer and tetramer forms with binding constants of about 10(3), 40, 18.10(4) M, respectively. The cooperativity parameter for peptide dimer binding is 2000. The peptide forms tetramer complexes with poly(A), poly(C), poly(G) also. The formation of a complex between the peptide tetramer and nucleic acid is accompanied by a significant increase in the fluorescence intensity. The cooperative binding of TVP dimers to poly(U), poly(A), poly(C) is accompanied by a dramatic decrease in the flexibility of polynucleotide chains. However, it has a small effect (if any) on the flexibility of the poly(G) chain. The observed similarity of thermodynamic, optical and hydrodynamic++ properties of TVP complexes with single-stranded and double-stranded nucleic acids may reflect a similarity in the geometries of peptide complexes with nucleic acids. Electron microscopy studies show that peptide binding to poly(U) and dsDNA leads to compactization of the nucleic acids caused by interaction between the peptide tetramers bound to a nucleic acid. At the first stage of the compactization process the well-organized rod-like particles are formed, each consisting of one or more single-stranded polynucleotide fibers. Increasing the peptide concentration stimulates a side-by-side association and folding of the rods with the formation of macromolecular "leech-like" structures with the thickness of 20-50 nm.     

Effects of polyamines on the activities of Escherichia coli ribonuclease I and II.

The effects of polyamines on the breakdown of synthetic polynucleotides [poly(A), poly(C), and poly(U)] by E. coli ribonuclease I [ribonucleate 3'-oligonucleotidohydrolase, EC 3.1.4.23] and ribonuclease II [EC 3.1.4.1] have been studied. The degradation of poly(C) by RNase II was stimulated by spermine and spermidine, while that of poly(A) by RNase II was not affected by polyamines. Under our standard experimental conditions, the breakdown of poly(U) by RNase II was inhibited slightly by polyamines. The stimulatory effect of spermine and spermidine on the breakdown of poly(C) occurred in the absence of monovalent cations but not in the absence of divalent cations. When polyamines were used as a stimulant of RNase II, the ratio of poly(C) degradation to poly(U) degradation was greater in the presence of inhibitors such as poly(G) than in their absence. Although the breakdown of all synthetic polynucleotides by RNase I was stimulated by polyamines, the degree of stimulation by polyamines was in the order poly(C)greater than poly(A)(see text)poly(U). However, the difference in degree of stimulation among polynucleotides decreased as monovalent cation concentration was increased.     

Isolation of a ribonuclease from fruiting bodies of the wild mushroom Termitomyces globulus

A ribonuclease, with a molecular mass of 13 kDa and a ubiquitin-like N-terminal sequence, has been isolated from fruiting bodies of the mushroom Termitomyces globulus. The ribonuclease demonstrated ribonucleolytic activity toward poly A, poly C, poly G and poly U, with the activity toward poly A and poly C being much higher than that toward poly G and poly U. The ribonuclease was unadsorbed on DEAE-cellulose but adsorbed on Affi-gel blue gel and CM-Sepharose. The enzyme required a temperature of 70 degrees C for expression of maximal activity. However, the enzyme expressed nearly the same optimal activity over a wide pH range of 5.0-8.0.     

The binding of Met-tRNAf to isolated 40-S ribosomal subunits and the formation of Met-tRNAf - 80-S-ribosome initiation complexes.

Different forms of 40-S ribosomal subunit, distinguishable by their buoyant densities on CsCl equilibrium density gradients, are formed when derived 40-S ribosomal subunits are incubated with partially purified reticulocyte ribosomal wash proteins. One of these subunits, the 1.37-g-cm-3 form is not present in the cell but the other two forms, the 1.40-g-cm-3 and 1.40-g-cm-3 subunits, are present in cell extracts. 35S label is bound to 1.37-g-cm-3 and 1.40-g-cm-s subunits when [35S]Met-tRANf, GTP and poly(A,U,G) are included in the incubations. The 35S-labelled 40-S subunits recovered, and the amount of 35S label bound to them, are changed if the [35S]Met-tRNAf-40-S-subunit-poly(A,U,G) complexes are first purified on sucrose gradients before analysing them on CsCl. The 1.37-g-cm-3 particle is no longer seen and the total quantity of 35S label on the 40-S subunits is 90% lower after sucrose gradient purification. Between 30% and 40% of the 40-S subunits bind [35S]Met-tRNAf when 1 mM GTP, an excess of ribosomal wash proteins and [35S]Met-tRNAf over derived 40-S subunits, and poly(A,U,G) or AUG is included in the incubations. The omission of poly(A,U,G) or AUG from the incubations substantially lowers the amount of subunit-bound 35S label ultimately recovered. With these incubations less than 10% of the 40-S subunits have bound [35S]Met-tRNAf. [35S]Met-tRNAf binding is affected by the nature of the RNA added. The addition of poly(U), rRNA and native 9-S golbin mRNA is without effect, whereas denatured globin mRNA is stimulatory. Maximum binding is obtained however with AUG. Poly(A,U,G) is less stimulatory than AUG but more stimulatory than denatured mRNA, suggesting that the number as well the accessibility of the AUG initiations condons determines the amount of 35S label bound. Similar results are obtained for the ribosomal-wash-dependent binding of [35S]Met-tRNAf to 80-S ribosomes. Contrary to the binding results, the ability of mRNA to stimulate protein synthesis is dependent on the integrity of the mRNA. Thus, native 9-S globin mRNA but not poly(A,U,G) stimulatex protein synthesis in the wheat germ system. HCHO-treated globin mRNA, although stimulatory, is 45% less effective than native mRNA. The addition of AUG, derived 60-S subunits and extra ribosomal wash is required for the formation of [35S]Met-tRNAf-80-S-ribosome complexes from sucrose-gradient-purified [35S]Met-tRNAf-40-S-subunit complexes. The 80-S ribosome complexes are able to form peptide bonds. Thus, if puromycin is added to the full incubations at zero time, no 35S label is present on the 80-S ribosome. 35S label is released as methionyl-puromycin. If the [35S]Met-tRNAf-40-S-subunit complexes are assembled with poly(A,U,G) or AUG in the incubations and then purified, only derived 60-S subunits are required to form [35S]Met-tRNAf-80-S-ribosome complexes. 35S label is not released from them when puromycin is added to the incubations unless extra ribosomal wash is also added.     

Isolation of a ribonuclease from sanchi ginseng (Panax pseudoginseng) flowers distinct from other ginseng ribonucleases

A single-chained ribonuclease was isolated from the aqueous extract of sanchi ginseng (Panax pseudoginseng) flowers. It exhibited a molecular mass of 23 kDa, an N-terminal sequence with some similarity to other enzymes involved in RNA metabolism but different from known ribonucleases, and considerably higher activity toward poly U than poly C and only slight activity toward poly A and poly G. The purification protocol entailed ion exchange chromatography on diethylaminoethyl (DEAE)-cellulose, affinity chromatography on Affi-gel blue gel, ion exchange chromatography on carboxymethyl (CM)-cellulose, and gel filtration on Superdex 75. The ribonuclease was unadsorbed on DEAE-cellulose and adsorbed on Affi-gel blue gel and CM-cellulose. Maximal activity of the ribonuclease was attained at pH 7. On either side of this pH the enzyme activity underwent a drastic decline. The enzyme activity was at its highest at 50 degrees C and dropped to about 20% of the maximal activity when the temperature was decreased to 20 degrees C or elevated to 80 degrees C. The characteristics of sanchi ginseng flower ribonuclease were different from those of the ribonucleases previously purified from sanchi ginseng and Chinese ginseng roots including ribonuclease from Chinese ginseng flowers which are morphologically very similar to sanchi ginseng flowers.     

Polyadenylic acid sequences in the RNA of Hyphomicrobium

Heterogeneous RNA containing polyadenylic acid [poly(A)] sequence has been isolated from Hyphomicrobium by affinity chromatography on oligothymidylic acid cellulose and polyuridylic acid Sepharose columns. About 0.1 to 0.3% of [3H]adenine-labeled RNA over a 60-min period is associated with poly(A) sequences. This percentage decreases to about 0.03 in a 20-h labeling period. The poly(A) tracts recovered after digestion with ribonuclease A and T1 are composed of greater than 95% adenine residues and are up to 200 nucleotides in length with a predominant range of 15 to 40 nucleotides. Adenosine and AMP are present in the ratio of 1:36 in alkaline digests of Hyphomicrobium poly(A) tracts. This is compatible with nucleotide lengths determined on acrylamide gels and location at the 3'-OH terminus of the RNA molecule.     

Unique nucleotide sequence adjacent to the poly (A) region in yeast RNA

Yeast cells growing in a low phosphate medium were labeled with a pulse of ³²P_i or [³H]adenine and harvested after 15 minutes. Total RNA was extracted and digested with ribonuclease T₁. Poly(A)-rich fragments were isolated from the digest by hybridization to poly(U) impregnated fiberglass filters. Gel filtration showed the fragments to have a uniform chain length of about sixteen. Analysis of the composition gave (A₁₁, C₄, U). Complete pancreatic ribonuclease and partial spleen phosphodiesterase digests gave the sequence of the 5′ end of the fragment as CpApApUp-. Since the fragment was a ribonuclease T₁ product, the data points to a unique sequence of at least five residues, -GpCpApApUp-, adjacent to the poly(A)-rich terminus of pulse-labeled yeast mRNA. The remainder of the poly(A)-rich fragment consists of A residues with a few randomly interspaced C residues. The known specificity of yeast poly(A) polymerase can account for the presence of C residues in poly(A) tracts.     

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.     

A distinctive ribonuclease from fresh fruiting bodies of the medicinal mushroom Ganoderma lucidum

A ribonuclease with an N-terminal sequence distinct from other mushroom ribonucleases was isolated from fresh fruiting bodies of the medicinal mushroom Ganoderma lucidum. The ribonuclease was adsorbed on DEAE-cellulose and Q-Sepharose, and unadsorbed on CM-Sepharose. It possessed a molecular mass of 42 kDa as judged by gel filtration by fast protein liquid chromatography on Superdex 75 and sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Its molecular mass was similar to that of straw mushroom ribonuclease but much higher compared with those of other mushroom ribonucleases. The ribonuclease was unique among mushroom ribonucleases in that it exhibited the highest potency toward poly(U), followed by poly(A). Its activity toward poly(G) and poly(C) was about one-half of that toward poly(A) and one-quarter of that toward poly(U). A pH of 4.0 and a temperature of 60 degrees C were required for optimal activity of the enzyme. The optimum pH was low compared with those reported for other mushroom ribonucleases.     

A method for isolation of oligo(uridylic acid)-containing messenger ribonucleic acid from HeLa cells

When cytoplasmic polyadenylated ribonucleic acid [poly(A+)RNA] from HeLa cells was treated with ribonuclease H (RNase H) and oligodeoxythymidylate [oligo(dT)] to remove its 3'-poly(A) tail, an increased binding to poly(A)-agarose was observed. The bound material, which comprised 4-6% of the initial RNA, contained 65-80% of the oligo(uridylic acid) [oligo(U)] sequences generated by RNase T1 digestion. Oligo(U) isolated from the bound fraction was shown to be 83% U and to have a U/G ratio of 33. In contrast, oligo(U) from the unbound material was 77% U and had a U/G ratio of 13, suggesting that it is shorter and less U rich than the oligo(U) in the bound fraction. On sucrose gradients, oligo(U+)RNA consistently sedimented with a larger s value than oligo(U-) RNA. The oligo(U) content of oligo(U+) RNA suggests one oligo(U) tract of 33 nucleotides per RNA molecule of 2000-3000 residues.     

A ribonuclease from human seminal plasma active on double-stranded RNA

A ribonuclease, active on single- and double-stranded RNAs, has been isolated from human seminal plasma 3-5 micrograms of enzyme were recovered per ml of seminal plasma, equivalent to 71% of total activity and a 2500-fold purification (measured with poly(A) X poly(U) as substrate) from the initial dialyzed material. Similar amounts of RNAase were found per g (wet weight) of human prostate, where the enzyme appears to be produced. Human seminal RNAase degrades poly(U) 3-times faster than poly(A) X poly(U), and poly(C) or viral single-stranded RNA about 10-times faster than poly(U). Degradation of poly(A) X poly(U), viral double-stranded RNA, and poly(A) by human seminal RNAase is 500-, 380- and 140-times more efficient, respectively, than by bovine RNAase A. The enzyme, a basic protein with maximum absorbance at 276 nm, occurs in two almost equivalent forms, one of which is glycosylated. Mr values of the glycosylated and non-glycosylated form are 21000 and 16000, respectively. The amino-acid composition of the RNAase is very similar to that of human pancreatic RNAase. The same is true for the carbohydrate content of its glycosylated form.     

A novel ribonuclease from fruiting bodies of the common edible mushroom Pleurotus eryngii

A ribonuclease with a temperature optimum of about 70 degrees C and a pH optimum of 6.5 was isolated from fruiting bodies of the mushroom Pleurotus eryngii. The ribonuclease was unadsorbed on DEAE-cellulose and adsorbed on Affi-gel blue gel and S-Sepharose. It possessed a molecular mass of 16 kDa, and exhibited higher ribonucleolytic activity toward poly A and poly G and lower ribonucleolytic activity toward poly C and poly U. Its N-terminal sequence was distinctly different from those of other mushroom ribonucleases, and resembled that of Pleurotus tuber-regium only by 40%. Furthermore, its thermostability characteristics, polyhomoribonucleotide specificity and molecular mass were dissimilar to those of other mushroom ribonucleases.     

Structural versatility of bovine ribonuclease A. Distinct conformers of trimeric and tetrameric aggregates of the enzyme.

Lyophilization of bovine ribonuclease A (RNase A; Sigma, type XII-A) from 40% acetic acid solutions leads to the formation of approximately 14 aggregated species that can be separated by ion-exchange chromatography. Several aggregates were identified, including two variously deamidated dimeric subspecies, two distinct trimeric and two distinct tetrameric RNase A conformers, besides the two forms of dimer characterized previously [Gotte, G. & Libonati, M. (1998) Two different forms of aggregated dimers of ribonuclease A. Biochim. Biophys. Acta 1386, 106-112]. We also have possible evidence for the existence of two forms of pentameric RNase A. The two forms of trimers and tetramers are characterized by: (a) slightly different gel filtration patterns; (b) different retention times in ion-exchange chromatography; and (c) different mobilities in cathodic gel electrophoresis under nondenaturing conditions. Therefore, they appear to have distinct structural organizations responsible for a different availability of their positively charged amino acid residues. All RNase A oligomers, in particular the two distinct trimeric and tetrameric conformers, degrade poly(A).poly(U), viral double-stranded RNA and polyadenylate with a catalytic efficiency that is in general higher for the more basic species. On the contrary, the activity of the RNase A oligomers, from dimer to pentamer, on yeast RNA and poly(C) (Kunitz assay) is lower than that of monomeric RNase A.     

Concentration and temperature effects in interactions of the dye pyronine G with polynucleotides

The interaction of poly(A) and poly(A).poly(U) with pyronine G dye depending on the concentration of components and temperature was studied spectrophotometrically in the visible and UV ranges at pH (6.86). It was found that the interaction of pyronine G with poly(A) and poly(A).poly(U) results in the formation of two types of complexes. The relation of the equilibrium concentrations of these complexes depends on the initial concentrations of the components in solution. The formation of complex I results in shifting the spectrum towards the short wave range with regard to the monomer band and reflects the aggregation of the dye cations. Complex II is characterized by the shift towards the long wave range. Complex II is formed in considerable amounts for poly(A).pyronine G system at large P/D and for poly(A).poly(U).pyronine G system at P/D = 5-6 and is probably due to the interaction between the dye and polynucleotides of the intercalation type or reflects the interaction between the dye and two negatively charged phosphate groups. Analysis of temperature measurements of spectra confirms the formation of various types of complexes in the system studied.