The reaction of ribonuclease inhibitor with modified ribonucleases

1. The effect of chemical modification of ribonuclease on its reaction with ribonuclease inhibitor has been studied. 2. Removal of free amino groups from the enzyme with nitrous acid or by acetylation did not affect the reaction. Some changes altered the stoicheiometry of the reaction and ribonuclease S was found to be inhibited linearly by increasing amounts of ribonuclease inhibitor, in contrast with ribonuclease A, which is inhibited in a non-linear way. One derivative of ribonuclease containing dimethylaminonaphthalenesulphonyl groups actually reacted with ribonuclease inhibitor to a greater extent (and linearly) than did the unaltered enzyme. 3. The positively charged histidine at the active site and the active enzyme did not appear to be necessary for the reaction since 1-carboxymethylhistidine-119-ribonuclease reacted with ribonuclease inhibitor to almost the same extent as the native enzyme. In general, any significant change in the conformation of ribonuclease was accompanied by a loss in its ability to combine with inhibitor. The presence of 8m-urea also prevented reaction of ribonuclease with inhibitor. 4. Some characteristics of the reaction of ribonuclease inhibitor, ribonuclease and deaminated ribonuclease with RNA and deaminated RNA were investigated.     

Action of crystalline acid carboxypeptidase from Penicillium janthinellum.

Acid carboxypeptidase (EC 3.4.12.-) crystallized from culture filtrate of Penicillium janthinellum has been investigated for its use in carboxy-terminal sequence determination of Z-Gly-Pro-Leu-Gly, Z-Gly-Pro-Leu-Gly-Pro, angiotensin I, native lysozyme, native ribonuclease T1, and reduced S-carboxy-methyl-lysozyme. The examination indicated that proline and glycine were liberated from Z-Gly-Pro-Leu-Gly-Pro. At high enzyme concentration, the enzyme catalyzed complete sequential release of amino acids from the carboxy-terminal leucine to the amino-terminal aspartic acid of angiotensin I. The enzyme released the carboxy-terminal leucine from native lysozyme, however, no release of the threonine from native ribonuclease T1 was observed after a prolonged period of incubation with the enzyme. The sequence of the first nine carboxy-terminal residues of denatured lysozyme, leucine, arginine, S-carboxymethyl-cysteine, glycine, arginine, isoleucine, tryptophane, alanine, and glutamine, could be deduced unequivocally from a time release plot of an incubation mixture with the enzyme.     

The subunit structure of calf thymus ribonuclease H i as revealed by immunological analysis

We have recently reported on the purification, subunit structure, and serological analysis of calf thymus ribonuclease H I and suggested a trimeric or tetrameric structure for the enzyme (Büsen, W., and Vogt, G. (1980) J. Biol. Chem. 255, 9434-9443). Continuation of our immunological analysis, using a protein blotting procedure for antigen detection and immunoaffinity chromatography, revealed that the native enzyme molecule is composed of polypeptides A and C with molecular weights of 31,600 and 24,800 respectively, in a molar ratio of 2 to 1. This is in accordance with a trimeric structure (A,A,C) for calf thymus ribonuclease H I. Polypeptides B and D, found in the most purified fraction, are shown to be generated during the early steps of the purification procedure, suggesting specific protein nicking which does not affect the native molecular weight of the enzyme.     

Ribonuclease H from rat liver. I. Partial purification and characterization of nuclear ribonuclease H1.

A ribonuclease H, an enzyme that specifically degrades the RNA moiety of RNA-DNA hybrid, has been partially purified from rat liver nuclei and characterized. Neither native or denatured DNA, nor single or double-stranded synthetic polyribonucleotides were degraded by the enzyme. The enzyme possesses a molecular weight of about 36,000 and requires alkaline pH, magnesium ions, and ammonium sulphate for maximum activity. The enzyme acts on the hybrid as an endonuclease, resulting in oligonucleotides with 3'-hydroxyl termini. The properties of this enzyme were distinct from those of the rat liver cytosol enzyme reported by Roewekamp and Sekeris in many respects, such as molecular weight, optimal pH and requirements for divalent cations. Preliminary experiments suggest that the nuclear enzyme is localized in the nucleoplasm and nucleoli. These results indicate that multiple forms of ribonuclease H exist in different regions of rat liver cells.     

Purification of cytosolic,latent endoribonuclease from porcine thyroid

An alkaline endoribonuclease was purified 1800-fold from the cytosolic, latent ribonuclease fraction of porcine thyroids by gentle procedures specifically designed to exclude both heating and acidification steps. Polyacrylamide gel electrophoresis revealed a broad peak of enzyme activity that was coincident with the stained protein band. As estimated by gel filtration chromatography the major form of the enzyme (59%) had a molecular weight of 51,000; the remainder of the activity was distributed among six minor forms. Carboxymethyl-cellulose chromatography showed that the enzyme had at least three interconvertible forms. The latent alkaline ribonuclease had a pH optimum of 8.1 in both Tris and 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid buffers and was stimulated by a number of monovalent chloride and potassium salts at ionic strengths between 10 and 70 mm; above 100 mm the salts were all inhibitory with the exception of ammonium chloride. At 1 mm both MgCl₂ and CaCl₂ were stimulatory, whereas CuCl₂ ZnCl₂ and EDTA were inhibitors. Both native and denatured DNA were slightly stimulatory. The porcine thyroid latent alkaline ribonuclease was specific for pyrimidine homopolymers and yielded a mixture of cyclic mononucleotides and oligonucleotides when incubated with poly(C). It did not hydrolyze 2′(3′)-cyclic CMP, purine homopolymers, native or denatured DNA or poly(A) · poly(U). Its activity toward rRNA was greater than toward tRNA and it cleaved the former to a mixture of mononucleotides and oligonucleotides. The properties of the intracellular, cytosolic, latent, alkaline ribonuclease distinguish it from pancreatic ribonuclease A and other nonsecretory ribonucleases.     

Monomeric selectively S-alkylated derivatives of seminal ribonuclease: preparation and properties

Procedures are described for preparing monomeric selectively S-carboxamido-methylated and S-aminoethylated derivatives of seminal ribonuclease. The main properties of the derivatives, including their extinction coefficients, have been determined. Their catalytic activities and that of the S-carboxymethyl derivative have been tested. On double-stranded RNA as a substrate the monomeric derivatives are less active than the native dimeric enzyme, but much more active than pancreatic ribonuclease. On yeast RNA as a substrate the amino-ethyl derivative is found to be less active (80%) than the native enzyme, while the other two are over 30 percent more active. The monomers are stable in solution and when lyophilized from acetic acid solution do not associate to the same extent as pancreatic or native seminal ribonucleases.     

Study of protein topography with flash photolytically generated nonspecific surface-labeling reagents: surface labeling of ribonuclease A

A method for nonspecifically labeling essentially all exposed residues of a protein is described. A reactive aryl nitrene is generated from N-(4-azido-2-nitrophenyl)-2-aminoethylsulfonate (NAP-Taurine), within 500 mus by flash photolysis in the presence of protein. The reactive nitrene is inserted in about 2 ms into those carbon-hydrogen bonds of the protein that are exposed to the solvent. The method is applied here to ribonuclease A to demonstrate the different degree of labeling of the native and denatured protein. On the basis of amino acid analysis, it appears that residues of the native protein that are buried in the interior of the molecule (as judged from the x-ray structure) do not react with the nitrene. However, when these residues (even nonreactive ones such as valine and proline) are exposed by denaturation of the protein, they do react with the nitrene. It is shown that native ribonuclease A retains 90% of its enzymatic activity when flashed in the absence of NAP-Taurine. This small loss in activity arises from the disruption of a limited portion of the native enzyme structure, as judged by circular dichroism, ultraviolet, and Raman spectra. The site of this limited disruption may be a portion of the enzyme surface near the Cys-26-Cys-84 disulfide bond. The utility of this surface labeling technique for studying the pathways of protein folding or unfolding is discussed.     

Study of the thermal denaturation of ribonuclease A by differential thermal analysis and susceptibility to proteolysis

1. The thermally induced change in conformation of ribonuclease A in solution was investigated by differential thermal analysis and the susceptibility of the enzyme to proteolytic digestion by ficin. 2. A transition with a mid-point of 60.5°C at pH4.2 was observed directly by differential thermal analysis and shown to be a property of the native structure. 3. At pH4.2 ribonuclease A is susceptible to ficin digestion at 60°C but not at 18°C. 4. Chromatographic analysis of the digestion products reveals that transient active intermediates are produced during the digestion. 5. Three of these intermediates were purified and partially characterized. 6. The nature of those sections of the ribonuclease molecule that are involved in the thermal transition is discussed.     

Isolation and Properties of Deoxyribonucleic Acid from Protoplasts of Cell Suspension Cultures of Ammi visnaga and Carrot (Daucus carota)

A procedure is described for the isolation of native DNA from protoplasts of ammi (Ammi visnaga) and carrot (Daucus carota) cells. Protoplasts were produced from 40 grams of fresh cells by enzyme hydrolysis and lysed with sodium dodecyl sulfate. The DNA was purified by treatment with pronase and ribonuclease. Final isolation was achieved by sucrose density gradient centrifugation.     

Thermodynamic nonideality as a probe of reversible protein unfolding effected by variations in pH and temperature: studies of ribonuclease

Thermodynamic nonideality arising from the space-filling effect of added sucrose is employed to confirm that the reversible unfolding of ribonuclease A effected by acid may be described as an equilibrium between native and unfolded states of the enzyme. However, the extent of the volume change is far too small for the larger isomer to be the fully expanded state, a result signifying that the acid-mediated unfolding of ribonuclease does not conform with the two-state equilibrium model of protein denaturation. Although the thermal denaturation of ribonuclease A is characterized by a larger increase in volume, quantitative reappraisal of published results on the effects of glycerol on this transition at pH 2.8 (Gekko, K., and Timasheff, S. N., 1981 Biochemistry 20, 4677-4686) leads to an estimated volume increase that is much smaller than that inferred from hydrodynamic studies--a disparity attributed to the dual actions of glycerol as a space-filling solute and as a ligand that binds preferentially to the thermally unfolded form of the enzyme. Even in this unfavorable circumstance the fact that glycerol exerts a net excluded volume effect at least confirms that the thermal unfolding of ribonuclease A is an equilibrium transition between two discrete states. The strengths and limitations of using thermodynamic nonideality as a probe of the two-state equilibrium model of protein denaturation are discussed in the light of these findings.     

The effects of cosolutes on protein dynamics: the reversal of denaturant-induced protein fluctuations by trimethylamine N-oxide

The protein stabilizing effects of the small molecule osmolyte, trimethylamine N-oxide, against chemical denaturant was investigated by NMR spin-relaxation measurements and model-free analysis. In the presence of 0.7 M guanidine hydrochloride increased picosecond-nanosecond dynamics are observed in the protein ribonuclease A. These increased fluctuations occur throughout the protein, but the most significant increases in flexibility occur at positions believed to be the first to unfold. Addition of 0.35 M trimethylamine N-oxide to this destabilized form of ribonuclease results in significant rigidification of the protein backbone as assessed by (1)H-(15)N order parameters. Statistically, these order parameters are the same as those measured in native ribonuclease indicating that TMAO reduces the amplitude of backbone fluctuations in a destabilized protein. These data suggest that TMAO restricts the bond vector motions on the protein energy landscape to resemble those motions that occur in the native protein and points to a relation between stability and dynamics in this enzyme.     

Early studies of native ribonuclease P,including discovery of its essential RNA component

Early work onE. coli ribonuclease P led to the detailed characterization of the native enzyme, which culminated in the discovery and initial characterization of M1 RNA and the demonstration thatE. coli RNase P contains an essential RNA component.Abbreviations MB methylene blue - MN micrococcal nuclease - RNaseP ribonuclease P - M1 RNA ribonuclease P RNA     

Increased proteolytic resistance of ribonuclease A by protein engineering.

Although highly stable toward unfolding, native ribonuclease A is known to be cleaved by unspecific proteases in the flexible loop region near Ala20. With the aim to create a protease-resistant ribonuclease A, Ala20 was substituted for Pro by site-directed mutagenesis. The resulting mutant enzyme was nearly identical to the wild-type enzyme in the near-UV and far-UV circular dichroism spectra, in its activity to 2',3'-cCMP and in its thermodynamic stability. However, the proteolytic resistance to proteinase K and subtilisin Carlsberg was extremely increased. Pseudo-first-order rate constants of proteolysis, determined by densitometric analysis of the bands of intact protein in SDS-PAGE, decreased by two orders of magnitude. In contrast, the rate constant of proteolysis with elastase was similar to that of the wild-type enzyme. These differences can be explained by the analysis of the fragments occurring in proteolysis with elastase. Ser21-Ser22 was identified as the main primary cleavage site in the degradation of the mutant enzyme by elastase. Obviously, this bond is not cleavable by proteinase K or subtilisin Carlsberg. The results demonstrate the high potential of a single mutation in protein stabilization to proteolytic degradation.     

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.     

Proton nuclear magnetic resonance studies of histidine residues in rat and other rodent pancreatic ribonucleases. Effects of pH and inhibitors

Proton nuclear magnetic resonance spectra of the histidine residues in bovine and rat ribonuclease have been compared. The changes in chemical shift on titration and on binding of cytidine-3′-monophosphate and cytidine-2′-monophosphate have been followed. In the presence of the cytidine derivatives the spectra of both enzymes resemble each other more than those of the free enzymes. With these inhibitors, two histidines in rat ribonuclease exhibit the same pK values and shifts as the active site residues histidine 12 and 119 in the bovine enzyme. Their pK values in the inhibitor-free rat enzyme are about 0.4 higher than in the beef enzyme, which can be explained by the substitution at the entrance of the active site cleft of arginine 39 in the beef enzyme by serine in the rat enzyme. Rat ribonuclease contains one histidine with a rather high pK value of 7.6. The cytidine derivatives affect its chemical shift in exactly the same way as the shift of histidine 48 in bovine ribonuclease. The high pK value of this residue in rat ribonuclease can be explained by assuming a strong hydrogen bridge with glutamic acid 16. The other two histidines in rat ribonuclease have rather low pK values of 6.1 and 6.3. The histidine with a pK value of 6.3 has been assigned to position 105 and that with a pK value of 6.1 to position 73.The closer resemblance of the active sites of bovine and rat ribonuclease in the presence of inhibitors than in the inhibitor-free enzymes makes the concept of induced fit interesting from an evolutionary point of view.The characteristic downfield shift of the protonated form of histidine 119 in the complexes of bovine and rat ribonuclease with cytidine-3′-monophosphate is not observed with uridine-3′-monophosphate, suggesting non-identical binding of these pyrimidine nucleotides.Some preliminary results on the nuclear magnetic resonance properties of the histidine residues in coypu and chinchilla pancreatic ribonuclease have been obtained.     

Complete amino-acid sequence of bovine seminal ribonuclease, a dimeric protein from seminal plasma

The complete amino-acid sequence of BS-RNAse, a dimeric ribonuclease isolated from bovine seminal plasma, was determined. The reduced and S-carboxymethylated subunit chain of the enzyme was cleaved by trypsin and chymotrypsin. The resulting peptides, purified by cation-exchange chromatography were sequenced by dansyl-Edman, subtractive Edman degradation and carboxypeptidase A and B digestion. Chymotryptic peptides were used for the alignment. Automated Edman degradation of the native protein, through the N-terminal 41 amino-acid residues, completed the sequence information. The subunit chain of BS-RNAse, composed of 124 amino-acid residues, with a molecular mass of 13,610 Da, is highly homologous (81%) to pancreatic ribonuclease A. A good degree of homology (31%) was also found with human angiogenin. No N-linked carbohydrate-attachment sites, such as Asn-X-Ser/Thr, were found in the protein.     

Partial denaturation of macromolecules by chemical agents

The denaturation of a macromolecule such as a polypeptide is considered in the case where the total number of noncovalent internal bonds broken in the binding process of the chemical agent is only a fraction, α_s, of the total number of noncovalent internal bonds involved in its helical native conformation. Starting from a two-parameter (s, σ) model of the helix–random coil transition of polypeptides, the transition temperature is derived as a function of the fraction α_s, and of the concentration and the binding constant of the chemical agent. The lower limit of the transition temperature and the corresponding slope of the transition curve are shown to depend on α_s. As an illustration, existing data on the partial acid denaturation of the enzymes ribonuclease A and muromidase are analyzed. The resulting average enthalpies of a noncovalent bond in the native ribonuclease A and muromidase are found to be 1.81 kcal/mole and 1.54 kcal/mole, respectively; the corresponding entropies are 5.4 and 4.4 cal/deg./mole, respectively. As a further example, existing data on a partially methylated enzyme ribonuclease A are also considered.     

Spermine stabilization of folded ribonuclease T1

The interaction of ribonuclease T1 with tetraprotonated spermine (SPM4+), Mg2+, phosphate and other ionic ligands at pH 6.0 was investigated in binding experiments at 25 degrees C and/or by their effects on the midpoint temperature for thermal unfolding of the enzyme. SPM4+ binding with the native protein at 25 degrees C was characterized by an association constant of approximately 2 x 10(4) M-1. This ligand also binds to the unfolded protein but with a approximately 35-fold lower affinity. Phosphate binds at the active site whereas Mg2+ and SPM4+ cations compete for binding at a polyanionic locus that probably involves residues Glu-28, Asp-29, and Glu-31 at the C-terminal end of the alpha-helix. Steady-state kinetic studies using minimal RNA substrates demonstrated that SPM4+ binding with the enzyme does not affect its catalytic activity. SPM4+ also preferentially binds with the folded form of the disulfide-reduced enzyme which has the same or slightly enhanced catalytic properties compared with native ribonuclease T1. The unfolding rate for the native protein in 8 M urea was approximately 8-fold lower in the presence of 0.05 M SPM4+. SPM4+ appears to increase the amplitude of an unobserved fast phase(s) for refolding of the native enzyme. A single kinetic phase characterized refolding of the reduced enzyme which was slightly faster than the slowest refolding phase for the native form.