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.     

The antitumor action of seminal ribonuclease tested with the plasmacytoma spleen colonization assay

The antitumor action of bovine seminal ribonuclease was evaluated with a quantitative assay based on the production of tumor foci in the spleens of mice injected with plasmacytoma cells. The antitumor action depended on the integrity of the catalytic site, and on the dimeric structure of the enzyme. A working hypothesis is proposed, based on these results, and on previous results obtained studying the antitumor action of seminal RNAase in vitro on cell cultures. According to this hypothesis, the antitumor action is based on the ability of seminal RNAase to interact at specific receptor sites on the tumor cell membrane, as well as on its RNA degrading ability.     

Human seminal ribonuclease. A tool to check the role of basic charges and glycosylation of a ribonuclease in the action of the enzyme on double-stranded RNA

Human seminal ribonuclease (a basic protein occurring in a glycosylated and in a non-glycosylated form) is very active against double-stranded RNAs (De Prisco, R., Sorrentino, S., Leone, E. and Libonati, M. (1984) Biochim. Biophys. Acta 788, 356-363). The action of the two enzyme forms on single-stranded and double-stranded substrates was studied as a function of pH and ionic strength. Results indicate (1) that glycosylation of the RNAase molecule does not affect enzyme action on single-stranded RNAs, while (2) degradation of double-stranded RNAs is moderately increased by the presence of carbohydrates in the enzyme molecule. Human seminal RNAase shows a marked helix-destabilizing activity on poly(dA-dT) X poly(dA-dT). Under various conditions, this action (1) is definitely stronger than that of bovine RNAase A, and (2) seems to be less dependent on the glycosylation than on the basicity of the enzyme protein. The remarkable activity of human seminal RNAase on double-stranded RNA may, at least partly, be related to the enzyme properties mentioned above.     

Interchain disulfide bridges in ribonuclease BS-1

RNAase BS-1, a dimeric ribonuclease isolated from bovine seminal plasma, is made up of two identical subunits whose amino acid sequence is homologous to the sequence of bovine pancreatic RNAase A. The dimeric structure, resistant to denaturating agents, is sensitive to thiol reagents even in the absence of denaturants. The isolation and characterization of a cystine peptide containing two adjacent $\text{1}\text{2}\text{cystine}$ residues is reported. As the peptide molecular weight is halved after reductive cleavage with dithiothreitol, a structure based on two interchain disulfide bonds between the two adjacent $\text{1}\text{2}\text{cystine}$ of each subunit is proposed. The singularity of such a structure for a small enzymatic protein is discussed.     

Reversible inactivation of ribonucleases by ADPribosylation

The activity of purified bovine seminal RNAase and pancreatic RNAase A (EC 3.1.27.5) has been investigated following in vitro ADPribosylation in the presence of nuclear ADPribosyltransferase (EC 2.4.2.30) and NAD+ X ADPribosylation of these enzymes was correlated with a significant decrease in their activities. Approximately three residues of ADPribose were present per mol of enzyme. Removal of the bound ADPribose restored enzyme activity to near normal levels. Similar results were obtained with nuclei isolated from bull seminal vesicles as an endogenous source of seminal RNAase and nuclear ADPribosyltransferase. The findings suggest that in vitro ADPribosylation has a reversible inactivating effect on ribonucleases.     

A method for determining oligo- and poly(ADP-ribosyl)ated enzymes and proteins in vitro

A new method to determine oligo- and poly(ADP-ribosyl)ated enzymes and proteins in vitro has been developed. This method is based on the facts that in Mg2+-depleted condition automodification of poly(ADP-ribose)polymerase is minimized and exogenously added acceptor protein is oligo(ADP-ribosyl)ated predominantly, and in Mg2+-fortified conditions the exogenous acceptor can be poly(ADP-ribosyl)ated. When 13 proteins, including several enzymes, were subjected to this system, dimeric bovine seminal RNase and micrococcal nuclease were found to be oligo(ADP-ribosyl)ated under Mg2+-depleted conditions but their activity was unchanged. Under Mg2+-fortified conditions however, the RNase was deactivated concomitantly with its extensive poly(ADP-ribosyl)ation. When dimeric bovine seminal RNase was monomerized in advance by treatment with dithiothreitol and urea, the enzyme lost ADP-ribose-accepting ability in spite of a significant residual enzyme activity. As used here successfully, the Mg2+-depleted and Mg2+-fortified ADP-ribosylation and subsequent chromatographic analysis of various proteins and enzymes might be an useful method for proving their oligo- and poly(ADP-ribosyl)ation.     

Bull semen RNAase revisited

A new RNAase, RNAase SPL, was discovered (Reddy et al., 1979), which constituted most of bull semen RNAase activity; it was reminiscent in many of its properties of the bovine seminal RNAase we have studied for many years (see References), but different from it in other respects. When the procedure devised by those authors for its isolation was repeated, we found that an RNAase SPL such as that described in the above-mentioned paper is not to be found in bovine seminal plasma.     

Dissociation of bovine seminal ribonuclease into catalytically active monomers by selective reduction and alkylation of the intersubunit disulfide bridges.

The hypothesis previously advanced that interchain disulfide bridges link the two identical subunits of bovine seminal ribonuclease BS-1 has been confirmed. The sedimentation rate and the electrophoretic mobility of the protein are not affected by denaturing agents unless thiol reagents are present in the denaturation mixtures. Reduction under controlled conditions results in the immediate cleavage of only 2 disulfide bonds out of 10 percent in the dimeric protein. Under these conditions, and the results do not change when partial reduction is followed by S-alkylation, 30% of the protein dissociates, while the remaining is found to consist of a dimeric species easily dissociable by denaturing agents without addition of thiol reagents. This indicates that the dimeric structure of seminal ribonuclease is maintained not only by disulfide bridges, but also by noncovalent forces. The protein derivative prepared by selective reduction and alkylation has been identified as monomeric bis-S-carboxymethylcysteine-31,32-ribonuclease BS-1. This is on the basis of the characterization of the 14C-labeled S-carboxymethylated peptides isolated from a thermolytic hydrolysate of the derivative prepared with iodo-2-[14C]acetic acid. Monomeric, selectively alkylated ribonuclease BS-1 is stable and catalytically active. The importance of such a derivative is discussed both in the light of the recent studies on the biological actions of seminal ribonuclease and as the fourth component of an experimental system of ribonucleases consisting of two homologous dimers (bovine seminal ribonuclease BS-1 and dimerized bovine pancreatic ribonuclease A) and two homologous monomers (ribonuclease A and the monomeric derivative of ribonuclease BS-1.     

How much is secondary structure responsible for resistance of double-stranded RNA to pancreatic ribonuclease A?

1. Double-stranded f2 sus11 or Qbeta RNAs, resistant to bovine pancreatic RNAase A in 0.15 M NaCl/0.015 M sodium citrate (SSC), are quickly and completely degraded at 10-fold lower ionic strength (0.1 X SSC) under otherwise similar conditions. At this ionic strength the secondary structure of double-stranded RNA is maintained, as judged by the following: (a) the unchanged resistance of double-stranded RNA and DNA, under similar low ionic strength conditions, to nuclease S1 from Aspergillus oryzae, in contrast with the sensitivity of the corresponding denatured nucleic acids to this enzyme, specific for single-stranded RNA and DNA; (b) the co-operative pattern of the thermal-transition profile of double-stranded RNA (with a Tm of 89 degrees C) in 0.1 X SSC. 2. Whereas in SSC bovine seminal RNAase (RNAase BS-1) and whale pancreatic RNAase show an activity on double-stranded RNA significantly higher than that of RNAase A, in 0.1 X SSC the activity of the latter enzyme on this substrate becomes distinctly higher than that of RNAase BS-1, and similar to that of whale RNAase. 3. From these results it is deduced that the secondary structure is probably not the only nor the most important variable in determining the susceptibility double-stranded RNA to ribonuclease. Other factors, such as the effect of ionic strength on the enzyme and/or the binding of enzyme to nucleic acids, may play an important role in the process of double-stranded RNA degradation by ribonucleases specific for single-stranded RNA.     

Influence of the surface potential on the Michaelis constant of membrane-bound enzymes: effect of membrane solubilization

We have purified from a membrane fraction of bovine brain a calmodulin-binding protein (calspectin) that shares a number of properties with erythrocyte spectrin: It has a heterodimeric structure with M_r 240 000 and 235 000 and binds to (dimeric form) or crosslinks (tetrameric form) F-actin. We show that calspectin (tetramer) is capable of inducing the polymerization of G-actin to actin filaments by increasing nucleation under conditions where actin alone polymerizes at a much slower rate. Thus, brain calspectin behaves in the same manner as erythrocyte spectrin, supporting the idea that, in conjunction with actin oligomers it comprises the cytoskeletal meshwork underlying the cytoplasmic surface of the nerve cell.     

Fast and high-yielding procedures for the isolation of bovine seminal RNAase

Fast and high yielding procedures for the isolation of bovine seminal RNAase are described. Homogeneous enzyme is prepared from seminal plasma in high yields in a single chromatographic step. Higher amounts (hundreds of mg) are easily prepared from seminal vesicles, a more available source of enzyme. Both procedures can be used also for the direct isolation of the isoenzymes of bovine seminal RNAase. An ultrarapid (1 hour) procedure is described for the preparation of mg amounts of pure enzyme, or of the individual isoenzymes, from seminal plasma.     

Cleavage of tRNA precursors by the RNA subunit of E. coli ribonuclease P (M1 RNA) is influenced by 3''-proximal CCA in the substrates

tRNA precursor molecules that contain the CCA sequence found at the 3' termini of all mature tRNAs are cleaved in vitro more readily by M1 RNA, the catalytic subunit of E. coli RNAase P, than precursors that lack this sequence. The sensitivity to the CCA sequence is not apparent when precursors are cleaved by the reconstituted RNAase P holoenzyme that contains both M1 RNA and the protein subunit. These results have been obtained with monomeric precursor molecules encoded by the E. coli and human chromosomes and with three dimeric precursor molecules encoded by the bacteriophage T4 genome. The data are in agreement with previous results concerning T4 tRNA biosynthesis in vivo and show that the CCA sequence is important for the processing of precursors to tRNAs.     

A new pyrimidine-specific ribonuclease from bovine seminal plasma that is active on both single and double-stranded polyribonucleotides and that can distinguish between Mg2+-containing and Mg2+-depleted naturally occurring RNAs

The purification to homogeneity of a new ribonuclease, named RNAase SPL, from bovine seminal plasma is described. This nuclease, like the bovine pancreatic RNAase A, is pyrimidine specific. Its activity on single-stranded synthetic polyribonucleotides such as poly(rU) is significantly higher than that of RNAase A. However, unlike RNAase A, RNAase SPL is highly active on a double-stranded RNA such as poly[r(A · U)], and shows extremely limited activity on naturally occurring RNAs, such as Escherichia coli RNA, prepared with Mg²⁺ present throughout the isolation procedure. Under conditions of limiting hydrolysis in which RNAase A degrades 60 to 90% of total E. coli RNA to acid-soluble material and the remaining to material having a molecular weight lower than that of transfer RNA, RNAase SPL does not yield any acid-soluble products: it does not appear to degrade tRNA or 5 S RNA, and causes only a small number of nicks in the remaining RNAs to yield a limiting digest containing products with molecular weights ranging between 10,000 and 150,000. Absence of Mg²⁺ during the isolation procedure, or heat denaturation of the RNA makes it as susceptible to RNAase SPL as it is to RNAase A.The above and other related observations reported here support the view that there are Mg²⁺-dependent structural features, besides single and doublestrandedness, in naturally occurring RNAs, that can be distinguished by using the two nucleases RNAase SPL and RNAase A.     

Differential, structure-dependent susceptibility of poly(A) and RNA to monomeric and dimeric pancreatic ribonuclease A.

Cross-linked dimers of bovine RNAase A are definitely more efficient than monomers at degrading polyadenylic acid under conditions of ionic strength and pH, where the polymer assumes either a double-helical or an ordered single-stranded, base-stacked structure. The opposite occurs, i.e., monomers of RNAase A are definitely more active than dimers,when poly(A) is digested by the two enzyme species under conditions where the conformation of the polymer is essentially that of a random coil. The same pattern of events occurs when total RNA from Escherichia coli or single-stranded RNA of f2 sus11 bacteriophage are used as substrates under opposite ionic-strength conditions. In the presence of high salt concentrations, favouring the formation and the stability of a secondary structure in self-complementary sequences of RNA, the ribonucleic acids are degraded at a higher rate by dimers than by monomers of bovine RNAase A. The opposite occurs in the presence of very low salt concentrations, i.e. when the RNAs are in solution presumably as random coils. These observations are discussed in the light of a hypothesis already advanced to understand the mechanism of enzymic degradation of secondary structures of polyribonucleotides.     

Characterization of an active single polypeptide form of the human immunodeficiency virus type 1 protease

The pepsin-like aspartyl proteases consist of a single polypeptide chain with topologically similar amino- and carboxyl-terminal domains, each of which contributes 1 aspartic acid residue to the active site. This structure has been proposed to have evolved by gene duplication and fusion from a dimeric enzyme composed of two identical polypeptide chains, such as the aspartyl protease (PRT) of human immunodeficiency virus type 1 (HIV-1). To determine if a single polypeptide form of the HIV-1 protease would be enzymatically active, two protease coding regions were linked to form a dimeric gene (pFGGP). Expression of this gene in Escherichia coli yielded a protein with the expected molecular mass of 22 kDa. The in vitro kinetic parameters of PRT and FGGP (where FGGP is the single polypeptide form of the HIV-1 protease with 2 glycine residues connecting the two subunits) for three peptide substrates are similar. Construction and analysis of a CheY-GAG-FGGP fusion protein demonstrated that FGGP is capable of precursor processing in vivo. Mutation of one or both of the active site aspartates to either asparagine or glutamate rendered the enzyme inactive, demonstrating that both active site aspartate residues are required for enzymatic activity.     

DSC study of reversible and irreversible thermal denaturation of concentrated globular protein solutions

A calorimetric study of the thermal denaturation of bovine serum albumin, RNAase and catalase in concentrated solutions (crystals) has been carried out. The results obtained for RNAase studied within the pH range 2.5-8.5 show that for concentrated solutions there is an interval of pH where, on cooling of the solution which had undergone denaturation, its renaturation is observed. In the case of concentrated and dilute solutions of RNAase these intervals coincide. The study of RNAase under such conditions at various heating rates shows that there is a range of rates in which the process of denaturation of concentrated solutions can be considered as reversible. The dependences of Td and Hd on pH and concentration of solutions have been determined. The denaturation enthalpy of concentrated solutions like in dilute ones, has been found to be independent of the pH of solutions, and the experimentally registered change has been proved to be the result of its dependence on temperature. A new method of determination of protein denaturation enthalpy under the conditions of intensive molecule aggregation is suggested. The forms of irreversibility as appearing in the calorimetric experiment were determined by comparing reversible and irreversible denaturation under continuous and step-heating regimes. It is shown that the decrease in Tmax and the narrowing of the heat absorption peak in the case of decreasing heating rates of protein solutions, observed under certain environmental conditions, results from the irreversibility of the denaturation process.     

Glimpses of the molecular mechanisms of β2-microglobulin fibril formation in vitro: Aggregation on a complex energy landscape

β₂-microglobulin (β₂m) is a 99-residue protein that aggregates to form amyloid fibrils in dialysis-related amyloidosis. The protein provides a powerful model for exploration of the structural molecular mechanisms of fibril formation from a full-length protein in vitro. Fibrils have been assembled from β₂m under both low pH conditions, where the precursor is disordered, and at neutral pH where the protein is initially natively folded. Here we discuss the roles of sequence and structure in amyloid formation, the current understanding of the structural mechanisms of the early stages of aggregation of β₂m at both low and neutral pH, and the common and distinct features of these assembly pathways.     

Crystal structure of the dimeric unswapped form of bovine seminal ribonuclease

Bovine seminal ribonuclease is a unique case of protein dimorphism, since it exists in two dimeric forms, with different biological and kinetic behavior, which interconvert into one another through three-dimensional swapping. Here we report the crystal structure, at 2.2 A resolution, of the unswapped form of bovine seminal ribonuclease. Besides completing the structural definition of bovine seminal ribonuclease conformational dimorphism, this study provides the structural basis to explain the dependence of the enzyme cooperative effects on its swapping state.     

Characterization of a tetrameric G4 form of acetylcholinesterase from bovine brain: a comparison with the dimeric G2 form of the electric organ

Globular forms (G forms) of acetylcholinesterase (AChE) are formed by monomers, dimers and tetramers of the catalytic subunits (G₁, G₂ and G₄). In this work the hydrophobic G₂ and G₄ AChE forms were purified to homogeneity from Discopyge electric organ and bovine caudate nucleus and studied from different points of view, including: velocity sedimentation, affinity to lectins and SDS-polyacrylamide gel electrophoresis under reducing and non-reducing conditions. The polypeptide composition of Discopyge electric organ G₂ is similar to Torpedo, however the pattern of the brain G₄ AChE is much complex. Under non-reducing conditions the catalytic subunit possesses a molecular weight of 65 kDa, however this value increases to 68 kDa after reduction, suggesting that intrachain-disulfide bonds are important in the folding of the catalytic subunits of the AChE. Also it was found that after mild proteolysis; the (¹²⁵I)-TID-20 kDa fragment decreased its molecular weight to approximately 10 kDa with little loss of AChE activity. Finally, we suggest a model for the organization of the different domains of the hydrophobic anchor fragment of the G₄ form.