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

Immune Modulation by Human Secreted RNases at the Extracellular Space

The ribonuclease A superfamily is a vertebrate-specific family of proteins that encompasses eight functional members in humans. The proteins are secreted by diverse innate immune cells, from blood cells to epithelial cells and their levels in our body fluids correlate with infection and inflammation processes. Recent studies ascribe a prominent role to secretory RNases in the extracellular space. Extracellular RNases endowed with immuno-modulatory and antimicrobial properties can participate in a wide variety of host defense tasks, from performing cellular housekeeping to maintaining body fluid sterility. Their expression and secretion are induced in response to a variety of injury stimuli. The secreted proteins can target damaged cells and facilitate their removal from the focus of infection or inflammation. Following tissue damage, RNases can participate in clearing RNA from cellular debris or work as signaling molecules to regulate the host response and contribute to tissue remodeling and repair. We provide here an overall perspective on the current knowledge of human RNases’ biological properties and their role in health and disease. The review also includes a brief description of other vertebrate family members and unrelated extracellular RNases that share common mechanisms of action. A better knowledge of RNase mechanism of actions and an understanding of their physiological roles should facilitate the development of novel therapeutics.

A ribonuclease inhibitor resistant dimer of human pancreatic ribonuclease displays specific antitumor activity

Human pancreatic ribonuclease (HPR) and bovine seminal ribonuclease (BS-RNase) are members of the RNase A superfamily. HPR is monomeric, whereas BS-RNase is dimeric. BS-RNase has strong antitumor and cytotoxic activities. However, HPR lacks cytotoxic activity as it is inactivated by intracellular cytosolic ribonuclease inhibitor (RI). Earlier, an RI-resistant cytotoxic variant of HPR, termed HPR-KNE was generated which contained three residues Lys7, Asn71 and Glu111 of HPR, known to interact with RI, mutated to alanine. In this study, we have engineered HPR to develop two dimeric RI-resistant molecules having anti-tumor activity. By incorporating two cysteines in HPR and HPR-KNE, we generated disulfide linked dimeric HPR, and a dimer of HPR-KNE, termed as HPR-D and HPR-KNE-D respectively. HPR-KNE-D was resistant towards inhibition by RI, and was found to be highly toxic to a variety of cells. On J774A.1 cells HPR-KNE-D was >375-fold more cytotoxic than HPR, and 15-fold more toxic than HPR-D. Further, on U373 cells HPR-KNE-D was >65-fold more cytotoxic than HPR, and 9-fold more toxic than HPR-D. The study demonstrates that combining dimerization and RI-resistance results in providing potent anti-tumor activity to HPR. The cytotoxic variants of HPR will be useful in designing protein therapeutics with low immunogenicity.

Double domain swapping in bovine seminal RNase: formation of distinct N- and C-swapped tetramers and multimers with increasing biological activities

Bovine seminal (BS) RNase, the unique natively dimeric member of the RNase super-family, represents a special case not only for its additional biological actions but also for the singular features of 3D domain swapping. The native enzyme is indeed a mixture of two isoforms: M = M, a dimer held together by two inter-subunit disulfide bonds, and MxM, 70% of the total, which, besides the two mentioned disulfides, is additionally stabilized by the swapping of its N-termini.

When lyophilized from 40% acetic acid, BS-RNase oligomerizes as the super-family proto-type RNase A does. In this paper, we induced BS-RNase self-association and analyzed the multimers by size-exclusion chromatography, cross-linking, electrophoresis, mutagenesis, dynamic light scattering, molecular modelling. Finally, we evaluated their enzymatic and cytotoxic activities.

Several BS-RNase domain-swapped oligomers were detected, including two tetramers, one exchanging only the N-termini, the other being either N- or C-swapped. The C-swapping event, confirmed by results on a BS-K113N mutant, has been firstly seen in BS-RNase here, and probably stabilizes also multimers larger than tetramers.

Interestingly, all BS-RNase oligomers are more enzymatically active than the native dimer and, above all, they display a cytotoxic activity that definitely increases with the molecular weight of the multimers. This latter feature, to date unknown for BS-RNase, suggests again that the self-association of RNases strongly modulates their biological and potentially therapeutic properties.

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.

The dual-mode quaternary structure of seminal RNase

Bovine seminal ribonuclease, the only dimeric ribonuclease described thus far, is found to exist in two different quaternary structure forms. In one, the N-terminal segment (residues 1-17) of each subunit is interchanged with the remaining segment of the other subunit, whereas in the second, such interchange does not occur. Functionally, they differ in that the catalytic activity of the form with interchange can be modulated by the substrate, whereas the noninterchange form exhibits no cooperativity. Each form can convert into the other, up to an equilibrium ratio, which is that found for the isolated protein. The results of refolding experiments of unfolded protein chains suggest that also in vivo the form lacking interchange may be produced first and is then partially transformed into the other dimeric form until equilibrium is reached. Although the implications of these findings may not be immediately apparent, they are intriguing and may have an impact on the unusual noncatalytic actions of the protein, such as its selective cytotoxicity toward tumor cells, activated T cells, and differentiated male germ cells.

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.