Relationships between nonhyperbolic kinetics and dimeric structure in ribonucleases

Mechanistic studies on substrate inhibition and substrate activation of ribonuclease A: experimental and in silico investigation

Ribonuclease A (RNase A) is an endonuclease that plays a significant role in antimicrobial activity by the cleavage and hydrolysis of ssRNA. In this study, the interactions between RNase A and cCMP have been investigated, through molecular docking and a 200 ns molecular dynamics simulation. The enzyme kinetic properties were analyzed using saturation curve, Eadie-Hofstee, and Hill plots. The docking results indicate that the cCMP-RNase A complexes are stabilized through hydrophobic interaction, hydrogen bonding, and π-π stacking interaction. The most binding site is observed in the catalytic cleft, especially at residue His12 and His119. Enzyme-ligand docking study indicates that cCMP binds to residues located in the internal cavity of the catalytic site and shows three phases of binding modes. The analysis of MD simulations shows that RMSD, Rg, and RMSF reach equilibrium. The ΔGbinding of the cCMP-RNase A was negative (-619.673 kJ/mol), The comparison between the results pre and post MD simulation showed that ΔGbinding after MD simulation causes to more stable the structure than before simulation. Experimental methods such as saturation, Eadie-Hofstee, and Hill plots confirm theoretical data and show three phases of binding modes as well. Two significant events are demonstrated in the interaction between RNase A and cCMP: substrate activation and substrate inhibition are observed in concentrations below and above 0.8 mM, respectively, for cCMP. Choosing the appropriate concentration of cCMP is very important in investigation of ribonuclease A's catalytic behavour, especially for exploration of the effects of some drugs on biological behaviours related to ribonuclease A.Communicated by Ramaswamy H. Sarma.

Dynamic properties of the N-terminal swapped dimer of ribonuclease A

Bovine pancreatic ribonuclease (RNase A) forms two 3-dimensional domain-swapped dimers with different quaternary structures. One dimer is characterized by the swapping of the C-terminal region (C-Dimer) and presents a rather loose structure. The other dimer (N-Dimer) exhibits a very compact structure with exchange of the N-terminal helix. Here we report the results of a molecular dynamics/essential dynamics (MD/ED) study carried out on the N-Dimer. This investigation, which represents the first MD/ED analysis on a three-dimensional domain-swapped enzyme, provides information on the dynamic properties of the active site residues as well as on the global motions of the dimer subunits. In particular, the analysis of the flexibility of the active site residues agrees well with recent crystallographic and site-directed mutagenesis studies on monomeric RNase A, thus indicating that domain swapping does not affect the dynamics of the active sites. A slight but significant rearrangement of N-Dimer quaternary structure, favored by the formation of additional hydrogen bonds at subunit interface, has been observed during the MD simulation. The analysis of collective movements reveals that each subunit of the dimer retains the functional breathing motion observed for RNase A. Interestingly, the breathing motion of the two subunits is dynamically coupled, as they open and close in phase. These correlated motions indicate the presence of active site intercommunications in this dimer. On these bases, we propose a speculative mechanism that may explain negative cooperativity in systems preserving structural symmetry during the allosteric transitions.

Thermodynamic stability of the two isoforms of bovine seminal ribonuclease

Bovine seminal ribonuclease (BS-RNase) is a dimeric protein with two identical subunits linked by two disulfide bridges, each subunit showing 80% of sequence identity with pancreatic RNase A. BS-RNase exists in two different quaternary conformations in solution: the MxM form, in which each subunit exchanges its alpha-helical N-terminal segment with its partner, and the M=M form with no exchange. By differential scanning microcalorimetry (DSC), the denaturation of the two dimeric forms of BS-RNase was found to be more complex than a simple two-state process. Monomeric derivatives of the dimeric protein follow instead a simple two-state mechanism, but are distinctly less stable than RNase A. The three-state N if I if D denaturation process of the two quaternary isoforms was interpreted by identifying in the dimers a central highly structured core, enclosing the covalently bonded subunit interface, which unfolds only after the periphery (mainly the N-terminal peptide) unfolds. Circular dichroism spectra of the two forms in the far-ultraviolet region show large differences between the secondary structure of the isoforms and that of the native BS-RNase mixture at equilibrium. This has been attributed to the presence in the equilibrium mixture of intermediate forms with displaced and disordered N-terminal alpha-helical segments.

Evolution of oligomeric proteins. The unusual case of a dimeric ribonuclease

The model system made up of a monomeric and a dimeric ribonuclease of the pancreatic-type superfamily has recently attracted the attention of investigators interested in the evolution of oligomeric proteins. In this system, bovine pancreatic ribonuclease (RNase A) is the monomeric prototype, and bovine seminal ribonuclease (BS-RNase) is the dimeric counterpart. However, this evolutionary case is unusual, as BS-RNase is the only dimeric member of the whole large superfamily comprising more than 100 identified members from amphibia, aves, reptilia and mammalia. Furthermore, although the seminal-type RNase gene can be traced back to the divergence of the ruminants, it is expressed only in a single species (Bos taurus). These unusual findings are discussed, as well as previous hypotheses on the evolution of seminal RNase. Furthermore, a new 'minimalist' hypothesis is proposed, in line with basic principles of structural biology and molecular evolution.

The subsites structure of bovine pancreatic ribonuclease A accounts for the abnormal kinetic behavior with cytidine 2',3'-cyclic phosphate

The kinetics of the hydrolysis of cytidine 2',3'-cyclic phosphate (C>p) to 3'-CMP by ribonuclease A are multiphasic at high substrate concentrations. We have investigated these kinetics by determining 3'-CMP formation both spectrophotometrically and by a highly specific and quantitative chemical sampling method. With the use of RNase A derivatives that lack a functional p2 binding subsite, evidence is presented that the abnormal kinetics with the native enzyme are caused by the sequential binding of the substrate to the several subsites that make up the active site of ribonuclease. The evidence is based on the following points. 1) Some of the unusual features found with native RNase A and C>p as substrate disappear when the derivatives lacking a functional p2 binding subsite are used. 2) The kcat/Km values with oligocytidylic acids of increasing lengths (ending in C>p) show a behavior that parallels the specific velocity with C>p at high concentrations: increase in going from the monomer to the trimer, a decrease from tetramer to hexamer, and then an increase in going to poly(C). 3) Adenosine increases the kcat obtained with a fixed concentration of C>p as substrate. 4) High concentrations of C>p protect the enzyme from digestion with subtilisin, which results in a more compact molecule, implying large substrate concentration-induced conformational changes. The data for the hydrolysis of C>p by RNase A can be fitted to a fifth order polynomial that has been derived from a kinetic scheme based on the sequential binding of several monomeric substrate molecules.

The crystal structure of a 3D domain-swapped dimer of RNase A at a 2.1-A resolution

The dimer of bovine pancreatic ribonuclease A (RNase A) discovered by Crestfield, Stein, and Moore in 1962 has been crystallized and its structure determined and refined to a 2.1-A resolution. The dimer is 3D domain-swapped. The N-terminal helix (residues 1-15) of each subunit is swapped into the major domain (residues 23-124) of the other subunit. The dimer of bull seminal ribonuclease (BS-RNase) is also known to be domain-swapped, but the relationship of the subunits within the two dimers is strikingly different. In the RNase A dimer, the 3-stranded beta sheets of the two subunits are hydrogen-bonded at their edges to form a continuous 6-stranded sheet across the dimer interface; in the BS-RNase dimer, it is instead the two helices that abut. Whereas the BS-RNase dimer has 2-fold molecular symmetry, the two subunits of the RNase A dimer are related by a rotation of approximately 160 degrees. Taken together, these structures show that intersubunit adhesion comes mainly from the swapped helical domain binding to the other subunit in the "closed interface" but that the overall architecture of the domain-swapped oligomer depends on the interactions in the second type of interface, the "open interface." The RNase A dimer crystals take up the dye Congo Red, but the structure of a Congo Red-stained crystal reveals no bound dye molecule. Dimer formation is inhibited by excess amounts of the swapped helical domain. The possible implications for amyloid formation are discussed.

3D domain swapping: a mechanism for oligomer assembly

3D domain swapping is a mechanism for forming oligomeric proteins from their monomers. In 3D domain swapping, one domain of a monomeric protein is replaced by the same domain from an identical protein chain. The result is an intertwined dimer or higher oligomer, with one domain of each subunit replaced by the identical domain from another subunit. The swapped "domain" can be as large as an entire tertiary globular domain, or as small as an alpha-helix or a strand of a beta-sheet. Examples of 3D domain swapping are reviewed that suggest domain swapping can serve as a mechanism for functional interconversion between monomers and oligomers, and that domain swapping may serve as a mechanism for evolution of some oligomeric proteins. Domain-swapped proteins present examples of a single protein chain folding into two distinct structures.

Hints on the evolutionary design of a dimeric RNase with special bioactions

Residues P19, L28, C31, and C32 have been implicated (Di Donato A, Cafaro V, D'Alessio G, 1994, J Biol Chem 269:17394-17396; Mazzarella L, Vitagliano L, Zagari A, 1995, Proc Natl Acad Sci USA: forthcoming) with key roles in determining the dimeric structure and the N-terminal domain swapping of seminal RNase. In an attempt to have a clearer understanding of the structural and functional significance of these residues in seminal RNase, a series of mutants of pancreatic RNase A was constructed in which one or more of the four residues were introduced into RNase A. The RNase mutants were examined for: (1) the ability to form dimers; (2) the capacity to exchange their N-terminal domains; (3) resistance to selective cleavage by subtilisin; and (4) antitumor activity. The experiments demonstrated that: (1) the presence of intersubunit disulfides is both necessary and sufficient for engendering a stably dimeric RNase; (2) all four residues play a role in determining the exchange of N-terminal domains; (3) the exchange is the molecular basis for the RNase antitumor action; and (4) this exchange is not a prerequisite in an evolutionary mechanism for the generation of dimeric RNases.

Structural basis for the biological activities of bovine seminal ribonuclease

Bovine seminal ribonuclease (BS-RNase) is a homolog of RNase A with special biological properties that include specific antitumor, aspermatogenic, and immuno-suppressive activities. Unlike RNase A, BS-RNase is a dimer cross-linked by disulfide bonds between Cys31 of one subunit and Cys32 of the other. At equilibrium, this dimer is a mixture of two distinct quaternary forms, M = M and M x M. The conversion of M = M to M x M entails the exchange of NH2-terminal alpha-helices between subunits. Here, the cytotoxic activities of purified M x M were shown to be greater than those of purified M = M, despite extensive equilibration of M = M and M x M during the time course of the assays. Replacing Cys31 or Cys32 with a serine residue did not compromise the enzymatic activity of dimeric BS-RNase, but reduced both the fraction of M x M at equilibrium and the cytotoxicity. We conclude that the M x M form is responsible for the special biological properties of BS-RNase. Since cytosolic ribonuclease inhibitor binds tightly to monomeric but not dimeric BS-RNase and only the M x M form can remain dimeric in the reducing environment of the cytosol, we propose that BS-RNase has evolved its M x M form to retain its lethal enzymatic activity in vivo.

Seminal RNase: a unique member of the ribonuclease superfamily

The RNase found in bull semen, although a member of the mammalian superfamily of ribonucleases, possesses some unusual properties. Besides its unique structure and enzymic properties, it displays antispermatogenic, antitumor and immunosuppressive activities. Seminal RNase belongs to an interesting group of RNases, the RISBASES (RIbonucleases with Special, i.e. non catalytic, Biological Actions) other members of which include angiogenin, selectively neurotoxic RNases, a lectin and the self-incompatibility factors from a flowering plant.

Immunosuppressive activity of bovine seminal RNase on T-cell proliferation

The interest in the immunosuppressive activity of mammalian seminal plasma depends largely on its putative role in the immunoregulation of both the male and female genital systems. We report here that the immunosuppressive action of bovine seminal plasma is based on the presence in this fluid of copious amounts of an immunosuppressive RNase, bovine seminal RNase. Studies of structure-function relationships have revealed that the immunosuppressive activity of seminal RNase depends on the integrity of the dimeric structure of the enzyme, as well as on the integrity of its catalytic function. While bovine seminal RNase has no effect on the secretion of interleukin-2 by T-cell cultures, the enzyme has been found to decrease drastically the expression of the alpha-chain of the interleukin-2 receptor on the T-cell membrane.

Dissociation and reconstitution of bovine seminal RNAase: construction of a hyperactive hybrid dimer

The quaternary structure of bovine seminal ribonuclease, the only dimeric protein in the superfamily of ribonucleases, is maintained both by noncovalent forces and by two intersubunit disulfides. The available monomeric derivatives of the enzyme may not be reassembled into dimers. They are catalytically active, but do not retain certain properties of the dimeric enzyme, such as: (i) the ability to respond cooperatively to increasing substrate concentrations in the rate-limiting reaction step; and (ii) the antitumor and immunosuppressive actions. In this report we described the preparation of stable monomers of seminal ribonuclease which can be reassociated into covalent dimers indistinguishable from the native protein. With this procedure a hybrid dimer was constructed, made up of a native subunit associated to a subunit catalytically inactivated by selective alkylation of the active site His-119. This dimer was found to have enzymic properties typical of monomeric ribonucleases, such as a hyperbolic saturation curve in the hydrolytic rate-limiting step of the reaction. However, the hybrid dimer was one order-of-magnitude more active than the dimeric enzyme.

A calorimetric approach to the study of the interactions of cytidine-3'-phosphate with bovine seminal ribonuclease

A calorimetric study at 25 degrees C is reported on the interaction between allosteric bovine seminal ribonuclease and cytidine-3'-phosphate. The results are compared with those obtained under identical experimental conditions for the interaction of pancreatic ribonuclease A and the same nucleotide. The analysis of the data provides evidence that the binding sites of seminal ribonuclease for cytidine-3'-phosphate are not equivalent, in agreement with previous equilibrium dialysis studies. A model with two sites with different affinities toward the nucleotide, the site with higher affinity resembling the binding site of pancreatic ribonuclease, is proposed. The values calculated for the thermodynamic parameters provide an insight of the forces involved in the interaction of the two enzymes with the nucleotide.

Interpreting the behavior of enzymes: purpose or pedigree?

To interpret the growing body of data describing the structural, physical, and chemical behaviors of biological macromolecules, some understanding must be developed to relate these behaviors to the evolutionary processes that created them. Behaviors that are the products of natural selection reflect biological function and offer clues to the underlying chemical principles. Nonselected behaviors reflect historical accident and random drift. This review considers experimental data relevant to distinguishing between nonfunctional and functional behaviors in biological macromolecules. In the first segment, tools are developed for building functional and historical models to explain macromolecular behavior. These tools are then used with recent experimental data to develop a general outline of the relationship between structure, behavior, and natural selection in proteins and nucleic acids. In segments published elsewhere, specific functional and historical models for three properties of enzymes--kinetics, stereospecificity, and specificity for cofactor structures--are examined. Functional models appear most suitable for explaining the kinetic behavior of proteins. A mixture of functional and historical models appears necessary to understand the stereospecificity of enzyme reactions. Specificity for cofactor structures appears best understood in light of purely historical models based on a hypothesis of an early form of life exclusively using RNA catalysis.

Selective deamidation and enzymatic methylation of seminal ribonuclease

Isoenzymatic forms alpha 2, alpha beta, and beta 2 of bovine seminal ribonuclease are generated by the transformation of beta-type into alpha-type subunit through deamidation of a single amide group [Di Donato, A., & D'Alessio, G. (1981) Biochemistry 20, 7232-7237]. The residue involved in this selective deamidation has been identified as Asn67. Deamidation occurs by formation of a cyclic imide intermediate involving the Gly at position 68. Opening of the cyclic imide may occur on either side of the nitrogen, generating both the normal alpha-aspartyl and an isoaspartyl residue at position 67. The alpha-carboxyl of the isoaspartyl residue is effectively methylated by bovine brain protein carboxylmethyltransferase.

Site-directed alkylation and site-site interactions in bovine seminal ribonuclease

Active-site histidine residues of bovine seminal RNase have been found to react with bromoacetic acid and with 2'(3')-O-bromoacetyluridine (BrAcUrd) at a much faster rate than free histidine. The former reagent reacts preferentially at the pros-N of His119, the latter is specific for the tele-N of His12. Alkylation with bromoacetic acid is mutually exclusive for either His119 or His12 and takes place predominantly at His119, while with BrAcUrd alkylation was found to be selective for His12. These results are very similar to those obtained with the same reagents on RNase A, confirming that seminal and pancreatic ribonucleases have similar geometries at their active sites. On the other hand, the kinetics of reaction of bromoacetyluridine with seminal RNase reveal a 'half-of-the sites' reactivity of the enzyme for this reagent, which is found to discriminate between the two structurally identical active sites of the dimeric enzyme.

Reacquisition of quaternary structure by fully reduced and denatured seminal ribonuclease

Air-regenerated monomers of bovine seminal ribonuclease have been found capable of reassociating into native dimers, whereas monomers refolded in the presence of a glutathione redox mixture do not reassociate into dimers [Smith, K. G., D'Alessio, G. and Schaffer, S. W. (1978) Biochemistry 17, 2633-2638]. The crucial step in the process of regeneration of dimers is an isomerization step, which the newly refolded monomers undergo in order to reassociate into dimers. The two sulfhydryls at sequence positions 31 and 32 of the seminal RNAase chain, forming in the native dimer the intersubunit disulfides, have been found to have an important role in the refolding of the monomeric intermediates, as well as in the regeneration of dimers.

Purification and characterization of two aminopeptidases from guinea-pig small-intestinal mucosa. Cavian intestinal tripeptide hydrolases

Two electrophoretically distinct cytosolic peptide hydrolases from guinea-pig small-intestinal mucosa have been highly purified by a six-step procedure comprising extraction from mucosal homogenate, ammonium sulphate fractionation, DEAE-cellulose chromatography, chromatofocusing, calcium phosphate chromatography and Sephadex G-100 gel filtration. They have similar apparent molecular masses as determined by gel filtration (Mr = 68 000) or by sodium dodecyl sulphate gel electrophoresis (Mr = 72 000). Both are aminopeptidases with optimum activity at pH 7.6. They are strongly inhibited by p-hydroxymercuribenzoate, o-phenanthroline and bestatin. Although both hydrolyse some dipeptides they have a distinctive kinetic preference for tripeptides composed of aromatic or non-polar residues. Their affinities for some tripeptides are particularly high and also the hydrolysis of some substrates exhibits biphasic kinetics. These two aminotripeptidases are similar but they can be differentiated from each other and from a number of other aminopeptidases.