Guanylyl 2'-5' guanosine as an inhibitor of ribonuclease T1

Large-scale motions within ribosomal 50S subunits as demonstrated using photolabile oligonucleotides

Photolabile oligonucleotides (PHONTs) bind to rRNA sequences to which they are complementary and, on photolysis, incorporate into neighboring ribosomal components. Here we report on photocrosslinking results obtained with PHONTs targeting 23S rRNA nucleotides 1882-1892, in the long lateral arm of the 50S subunit (PHONT 1892), and 1085-1093, in the L11 binding domain (PHONT 1093). Photolysis of the PHONT 1892.50S and PHONT 1093.50S complexes leads to formation of 'long-range' crosslinks from C1892 to U1094/A1095 and G1950, and from G1093 to U1712/1716 and U1926, that are clearly incompatible with published crystal structures of 50S subunits. These results provide strong evidence that within the 50S subunit (a) the L11 binding domain can extend in an arm-like fashion, accessing large areas of the ribosome, and (b) the lateral arm can bend about the noncanonical helix at its center. Such motions may have functional relevance in identifying regions that undergo major conformational change as the ribosome moves through its catalytic cycle.

Selective removal of ribonucleases from solution with covalently anchored macromolecular inhibitor

Poly[2'-O-(2,4-dinitrophenyl)]poly(A)[DNP-poly(A)] has been found to be a potent inhibitor in solution for RNases A, B, S, T1, T2 and H as well as phosphodiesterases I and II. Kinetic measurements with RNase B and RNase T1 showed DNP-poly(A) to be a reversible competitive inhibitor with K1 equal to 1.03 and 1.05 microM, respectively. Data on the quenching of fluorescence of RNase T1 by DNP-poly(A) indicate the existence of more than one RNase-binding site in each DNP-poly(A) molecule. By attaching each DNP-poly(A) molecule at one end covalently to oxirane acrylic beads, an affinity column was prepared for selective removal of RNases from aqueous solutions by simple filtration. It was found that a 1000-fold reduction in RNase concentration can be obtained by passing either 7.0 microM or 7.0 nM RNase A solution through a 5-cm-long column. The column can be saturated by passing through a concentrated RNase solution and subsequently regenerated by washing with salt solution. The regenerated column can be used repeatedly with no significant decrease in RNase-binding affinity and capacity. By titration of the derivatized beads with RNase, the first dissociation constant (Kd) and binding capacity for the bound enzyme can be determined. The (Kd) was found to be 0.66 microM for RNase B and 0.48 microM for RNase T1; the corresponding binding capacities were found to be 21.0 x (10)-8 and 9.6 x (10)-8 mol/g, respectively.

Computer modeling studies on the binding of 2',5'-linked dinucleoside phosphates to ribonuclease T1-influence of subsite interactions on the substrate specificity

The modes of binding of Gp(2',5')A, Gp(2',5')C, Gp(2',5')G and Gp(2',5')U to RNase T1 have been determined by computer modelling studies. All these dinucleoside phosphates assume extended conformations in the active site leading to better interactions with the enzyme. The 5'-terminal guanine of all these ligands is placed in the primary base binding site of the enzyme in an orientation similar to that of 2'-GMP in the RNase T1-2'-GMP complex. The 2'-terminal purines are placed close to the hydrophobic pocket formed by the residues Gly71, Ser72, Pro73 and Gly74 which occur in a loop region. However, the orientation of the 2'-terminal pyrimidines is different from that of 2'-terminal purines. This perhaps explains the higher binding affinity of the 2',5'-linked guanine dinucleoside phosphates with 2'-terminal purines than those with 2'-terminal pyrimidines. A comparison of the binding of the guanine dinucleoside phosphates with 2',5'- and 3',5'-linkages suggests significant differences in the ribose pucker and hydrogen bonding interactions between the catalytic residues and the bound nucleoside phosphate implying that 2',5'-linked dinucleoside phosphates may not be the ideal ligands to probe the role of the catalytic amino acid residues. A change in the amino acid sequence in the surface loop region formed by the residues Gly71 to Gly74 drastically affects the conformation of the base binding subsite, and this may account for the inactivity of the enzyme with altered sequence i.e., with Pro, Gly and Ser at positions 71 to 73 respectively. These results thus suggest that in addition to recognition and catalytic sites, interactions at the loop regions which constitute the subsite for base binding are also crucial in determining the substrate specificity.

Three-dimensional structure of ribonuclease T1 complexed with guanylyl-2',5'-guanosine at 1.8 A resolution

The enzyme ribonuclease T1 (RNase T1) isolated from Aspergillus oryzae was cocrystallized with the specific inhibitor guanylyl-2',5'-guanosine (2',5'-GpG) and the structure refined by the stereochemically restrained least-squares refinement method to a crystallographic R-factor of 14.9% for X-ray data above 3 sigma in the resolution range 6 to 1.8 A. The refined model consists of 781 protein atoms, 43 inhibitor atoms in a major site and 29 inhibitor atoms in a minor site, 107 water oxygen atoms, and a metal site assigned as Ca. At the end of the refinement, the orientation of His, Asn and Gln side-chains was reinterpreted on the basis of two-dimensional nuclear magnetic resonance data. The crystal packing and enzyme conformation of the RNase T1/2',5'-GpG complex and of the near-isomorphous RNase T1/2'-GMP complex are comparable. The root-mean-square deviation is 0.73 A between equivalent protein atoms. Differences in the unit cell dimensions are mainly due to the bound inhibitor. The 5'-terminal guanine of 2',5'-GpG binds to RNase T1 in much the same way as in the 2'-GMP complex. In contrast, the hydrogen bonds between the catalytic center and the phosphate group are different and the 3'-terminal guanine forms no hydrogen bonds with the enzyme. This poor binding is reflected in a 2-fold disorder of 2',5'-GpG (except the 5'-terminal guanine), which originates from differences in the pucker of the 5'-terminal ribose. The pucker is C2'-exo for the major site (2/3 occupancy) and C1'-endo for the minor site (1/3 occupancy). The orientation of the major site is stabilized through stacking interactions between the 3'-terminal guanine and His92, an amino acid necessary for catalysis. This might explain the high inhibition rate observed for 2',5'-GpG, which exceeds that of all other inhibitors of type 2',5'-GpN. On the basis of distance criteria, one solvent peak in the electron density was identified as metal ion, probably Ca2+. The ion is co-ordinated by the two Asp15 carboxylate oxygen atoms and by six water molecules. The co-ordination polyhedron displays approximate 4m2 symmetry.

Studies of catalysis by ribonuclease U2. Steady-state kinetics for transphosphorylation of oligonucleotide and synthetic substrates

The values of the steady-state kinetic parameters for the RNase, U2 catalyzed transphosphorylation were measured for several di- and trinucleotides such as ApXp (X = A, C, G, or U), ApYpGp, and YpApGp (Y = C or U). The pH dependence of kcat/Km for ApUp indicated a dependence for catalysis upon an unprotonated group with pK = 3.8 and two proton-associated groups with pK = 4.4 and 5.0. As judged from kcat/Km values, ApUpGp and ApCpGp are better substrates than the corresponding parent dimers, ApUp and ApCp, respectively. By contrast, the kcat/Km for UpApGp was about 1/20 relative to that of the parent dimer, ApGp. The results were compared for possible thermodynamic and structural information about the chemical consequences. The inhibition of the RNase U2 catalyzed reaction of ApUp by a series of nucleosides and nucleotides was also studied. Evidence for similarities and dissimilarities in the binding and catalysis by RNase U2 and RNase T1 is presented.