Angiogenin, a blood vessel inducing protein isolated from a human tumor cell line, has been found to exhibit ribonucleolytic activity. It catalyzes the cleavage of both 28S and 18S ribosomal RNA as determined by agarose gel electrophoresis. The major products formed with these substrates are 100-500 nucleotides in length. In contrast, angiogenin is inactive toward all of the more conventional substrates of the homologous pancreatic ribonucleases. In particular, it does not produce detectable amounts of acid-soluble fragments from high molecular weight wheat germ RNA, poly(C), or poly(U), nor does it hydrolyze cytidine or uridine cyclic 2',3'-phosphate. The high degree of sequence homology between angiogenin and the pancreatic ribonucleases, which includes all three catalytic residues, His-12, Lys-41, and His-119, has thus identified the chemical nature of a potential angiogenin substrate. These results may bear importantly on the physiological function of angiogenin.
Angiogenin, a potent inducer of neovascularization, is the only angiogenic molecule known to exhibit ribonucleolytic activity. Its overall structure, as determined at 2.4 A, is similarto that of pancreatic ribonuclease A, but it differs markedly in several distinct areas, particularly the ribonucleolytic active center and the putative receptor binding site, both of which are critically involved in biological function. Most sri ly, the site that is spatially analogous to that for pyrimidine binding in ribonuclease A differs siificantly in conformation and is "obstructed" by glutamine-117. Movement of this and adjacent residues may be required for substrate binding to anginin and, hence, constitute a key part of its menism of action.Human angiogenin (Ang), a single-chain polypeptide (Mr 14,124) present in tumor cell conditioned medium and normal serum (1, 2), is a potent inducer of neovascularization (1). It binds specifically to endothelial cells in culture (3) and elicits second-messenger responses (4). It also binds heparin (38), can serve as a substratum for endothelial cell adhesion (5), and is translocated to the nucleus (39). Among angiogenic molecules, Ang is unique in that it is a ribonucleolytic enzyme (6) with an amino acid sequence 33% identical to that of bovine pancreatic ribonuclease (RNase) A (7). Moreover, although Ang has the same general catalytic properties as RNase A-it cleaves preferentially on the 3' side of pyrimidines and follows a transphosphorylation/hydrolysis mechanism-its activity differs markedly both in magnitude and in specificity (6,8).Efforts to delineate the structural basis for the characteristic enzymatic and biological activities of Ang have been guided in large part by the vast wealth of existing information on RNase A, much of it derived from x-ray crystallography (9,10
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The dissociation rate constant of the angiogenin-placental ribonuclease inhibitor complex was determined by measuring the release of free angiogenin from the complex in the presence of scavenger for free placental ribonuclease inhibitor (PRI). In 0.1 M NaCl, pH 6, 25 degrees C, this value is 1.3 X 10(-7) s-1 (t1/2 congruent to 60 days). The Ki value for the binding of PRI to angiogenin, calculated from the association and dissociation rate constants, is 7.1 X 10(-16) M. The corresponding values for the interaction of RNase A with PRI, determined by similar means, are both considerably higher: the dissociation rate constant is 1.5 X 10(-5) s-1 (t1/2 = 13 h), and the Ki value is 4.4 X 10(-14) M. Thus, PRI binds about 60 times more tightly to angiogenin than to RNase A. The effect of increasing sodium chloride concentration on the binding of PRI to RNase A was explored by Henderson plots. The Ki value increases to 39 pM in 0.5 M NaCl and to 950 pM in 1 M NaCl, suggesting the importance of ionic interactions. The mode of inhibition of RNase A by PRI was determined by examining the effect of a competitive inhibitor of RNase A, cytidine 2'-phosphate, on the association rate of PRI with RNase A. Increasing concentrations of cytidine 2'-phosphate decrease the association rate in a manner consistent with a competitive mode of inhibition.
The roles of His-13 and His-114 in the ribonucleolytic and angiogenic activities of human angiogenin have been investigated by site-directed mutagenesis. Replacement of either residue by alanine (H13A and H114A) decreases enzymatic activity toward tRNA by at least 10,000-fold and virtually abolishes 10,000-fold and virtually abolishes angiogenic activity in the chick embryo chorioallantoic membrane assay. Both the H13A and H114A mutant proteins compete effectively with angiogenin in the latter assay; only a 5-fold molar excess of H13A over unmodified protein is required for complete inhibition. The His----Ala substitutions, however, do not have any significant effect on the interaction of angiogenin with human placental ribonuclease inhibitor, an extremely potent inhibitor of angiogenin (Ki approximately 7 x 10(-16 M) previously shown to interact with another active-site residue, Lys-40. The effects of more conservative replacements-glutamine at position 13 and asparagine at position 114--were also examined. While the enzymatic activity of the H114N mutant was at least 3300-fold less than for the unmodified protein, the H13Q derivative had only 300-fold reduced activity toward tRNA and cytidylyl(3'----5') adenosine. Both substitutions substantially decreased angiogenic activity. The parallel effects on ribonucleolytic and biological activities observed with all four mutant proteins provide strong evidence that the latter activity of angiogenin is dependent on a functional enzymatic active site. The capacity of the H13A and H114A derivatives to compete with angiogenin in the chorioallantoic membrane assay suggests several additional features of the biological mode of action of this protein.
Human placental RNase inhibitor (hRI), a leucine-rich repeat protein, binds the blood vessel-inducing protein human angiogenin (Ang) with extraordinary affinity (Ki <1 fM). Here we report a 2.0 A resolution crystal structure for the hRI-Ang complex that, together with extensive mutagenesis data from earlier studies, reveals the molecular features of this tight interaction. The hRI-Ang binding interface is large and encompasses 26 residues from hRI and 24 from Ang, recruited from multiple domains of both proteins. However, a substantial fraction of the energetically important contacts involve only a single region of each: the C-terminal segment 434-460 of hRI and the ribonucleolytic active centre of Ang, most notably the catalytic residue Lys40. Although the overall docking of Ang resembles that observed for RNase A in the crystal structure of its complex with the porcine RNase inhibitor, the vast majority of the interactions in the two complexes are distinctive, indicating that the broad specificity of the inhibitor for pancreatic RNase superfamily proteins is based largely on its capacity to recognize features unique to each of them. The implications of these findings for the development of small, hRI-based inhibitors of Ang for therapeutic use are discussed.
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