"Zero-length" dimers of ribonuclease A: further characterization and no evidence of cytotoxicity.

"Zero-length" dimers of ribonuclease A, a novel type of dimers formed by two RNase A molecules bound to each other through a zero-length amide bond [Simons, B. L., et al.

Carbodiimide EDC induces cross-links that stabilize RNase A C-dimer against dissociation: EDC adducts can affect protein net charge, conformation, and activity.

RNase A self-associates under certain conditions to form a series of domain-swapped oligomers. These oligomers show high catalytic activity against double-stranded RNA and striking antitumor actions that are lacking in the monomer. However, the dissociation of these metastable oligomers limits their therapeutic potential.

Oligomerization of ribonuclease A under reducing conditions.

By lyophilization from 40% acetic acid solutions, bovine ribonuclease A forms well characterized, three-dimensional domain-swapped oligomers: dimers, trimers, tetramers, and higher order multimers. Each oligomeric species consists of at least two conformers. Identical oligomers also form by thermally-inducing the oligomerization of highly concentrated RNase A dissolved in fluids endowed with various denaturing power.

Cytotoxicity of polyspermine-ribonuclease A and polyspermine-dimeric ribonuclease A.

Polyspermine-ribonuclease A (PS-RNase A) and polyspermine-dimeric ribonuclease A (PS-dimeric RNase A) were prepared by cross-linking ribonuclease A or its covalently linked dimer to polyspermine (PS) using dimethyl suberimidate. The two RNase A derivatives were tested for a possible antitumor action. The in vitro and in vivo cytotoxic activity of PS-RNase A, although strong, is not higher than that known for free polyspermine.

Increase of RNase a N-terminus polarity or C-terminus apolarity changes the two domains' propensity to swap and form the two dimeric conformers of the protein.

Do the polarities of the N-terminus or the apolarity of the C-terminus of bovine RNase A influence the relative yields of its two 3D domain-swapped dimeric conformers, the N-dimer and C-dimer? We have addressed this question by substituting Ala-4 or Ala-5 with serine (A4S and A5S mutants) or Ser-123 with alanine (S123A mutant) through site-directed mutagenesis. Both the polarity of the N-terminus and the apolarity of the C-terminus of RNase A were, therefore, increased. CD spectra revealed no significant differences between the secondary structures of the mutants and native RNase A.

Formation, structure, and dissociation of the ribonuclease S three-dimensional domain-swapped dimer.

Post-translational events, such as proteolysis, are believed to play essential roles in amyloid formation in vivo. Ribonuclease A forms oligomers by the three-dimensional domain-swapping mechanism. Here, we demonstrate the ability of ribonuclease S, a proteolytically cleaved form of ribonuclease A, to oligomerize efficiently.

Three-dimensional domain-swapped oligomers of ribonuclease A: identification of a fifth tetramer, pentamers and hexamers, and detection of trace heptameric, octameric and nonameric species.

By lyophilization from 40% acetic acid solutions, bovine pancreatic Ribonuclease A forms three-dimensional domain-swapped dimers, trimers, and tetramers that can be separated by cation-exchange chromatography. Each oligomeric species consists of at least two conformers, one less basic, one more basic. The structures of the two dimers and one trimer have been solved.

Oligomerization of ribonuclease A: two novel three-dimensional domain-swapped tetramers.

By lyophilization from 40% acetic acid solutions, bovine ribonuclease A forms several types of three-dimensional domain-swapped oligomers: dimers, trimers, tetramers, and higher order multimers. Each oligomeric species comprehends at least two conformers: one less basic and one more basic. The structures of the two dimers and one trimer have been solved.

Oligomerization of bovine ribonuclease A: structural and functional features of its multimers.

Bovine pancreatic RNase A (ribonuclease A) aggregates to form various types of catalytically active oligomers during lyophilization from aqueous acetic acid solutions. Each oligomeric species is present in at least two conformational isomers. The structures of two dimers and one of the two trimers have been solved, while plausible models have been proposed for the structures of a second trimer and two tetrameric conformers.

Glycosylation and specific deamidation of ribonuclease B affect the formation of three-dimensional domain-swapped oligomers.

RNase A oligomerizes via the three-dimensional domain-swapping mechanism to form a variety of oligomers, including two dimers. One, called the N-dimer, forms by swapping of the N termini of the protein; the other, called the C-dimer, forms by swapping of the C termini. RNase B is identical in protein sequence and conformation to RNase A, but its Asn34 bears an oligosaccharide chain that might affect oligomerization.

Antitumor activity and other biological actions of oligomers of ribonuclease A.

Dimers, trimers, and tetramers of bovine ribonuclease A, obtained by lyophilization of the enzyme from 40% acetic acid solutions, were purified and isolated by cation exchange chromatography. The two conformers constituting each aggregated species were assayed for their antitumor, aspermatogenic, or embryotoxic activities in comparison with monomeric RNase A and bovine seminal RNase, which is dimeric in nature. The antitumor action was tested in vitro on ML-2 (human myeloid leukemia) and HL-60 (human myeloid cell line) cells and in vivo on the growth of human non-pigmented melanoma (line UB900518) transplanted subcutaneously in nude mice.

Thermal aggregation of ribonuclease A. A contribution to the understanding of the role of 3D domain swapping in protein aggregation.

By lyophilizing RNase A from 40% acetic acid solutions, two dimeric aggregates, the "minor" and "major" dimers (named here N-dimer and C-dimer, respectively), form by 3D domain swapping at a ratio of 1:4. Trimeric and tetrameric aggregates are also obtained. The two dimers and the higher oligomers also form without a lyophilization step.

Structures of the two 3D domain-swapped RNase A trimers.

When concentrated in mildly acidic solutions, bovine pancreatic ribonuclease (RNase A) forms long-lived oligomers including two types of dimer, two types of trimer, and higher oligomers. In previous crystallographic work, we found that the major dimeric component forms by a swapping of the C-terminal beta-strands between the monomers, and that the minor dimeric component forms by swapping the N-terminal alpha-helices of the monomers. On the basis of these structures, we proposed that a linear RNase A trimer can form from a central molecule that simultaneously swaps its N-terminal helix with a second RNase A molecule and its C-terminal strand with a third molecule.