The effective synthesis of uridylyl/3'-5'/5-methylcytidylyl/3'-5'/guanosine.

The triester method was adapted to the synthesis of uridylyl/3'-5'/5-methylcytidylyl/3'-5'/guanosine. As the protecting groups 4-methoxy-5,6-dihydro-2H-pyran for 2'-OH and 5'-OH groups of uridine and 2'-OH group of 5-methylcytidine, methoxymethylidene for I:3'-cis-diol system of guanosine, and benzoyl for the amino groups of 5-methylcytidine and guanosine were used. The obtained product was characterised by UV, electrophoresis, chromatography, an enzymatic digestion and alkaline hydrolysis.     

Crystal structures of the ribonuclease MC1 mutants N71T and N71S in complex with 5'-GMP: structural basis for alterations in substrate specificity

Ribonuclease MC1 (RNase MC1), isolated from bitter gourd seeds, is a uridine specific RNase belonging to the RNase T2 family. Mutations of Asn71 in RNase MC1 to the amino acids Thr (N71T) and Ser (N71S) in guanosine preferential RNases altered the substrate specificity from uridine specific to guanosine specific, as shown by the transphosphorylation of diribonucleoside monophosphates [Numata, T., et al. (2001) Biochemistry 40, 524-530]. To elucidate the structural basis for the alteration of substrate specificity, crystal structures of the RNase MC1 mutants N71T and N71S, free or complexed with 5'-GMP, were determined at resolutions higher than 2 A. In the N71T-5'-GMP and N71S-5'-GMP complexes, the guanine moiety was, as in the case of the uracil moiety bound to wild-type RNase MC1, firmly stabilized in the B2 site by an extensive network of hydrogen bonds and hydrophobic interactions. Structure comparisons showed that mutations of Asn71 to Thr or Ser cause an enlargement of the B2 site, which then make it feasible to insert a guanine base into the B2 site of mutants N71T and N71S. This binding further allows for hydrogen bonding interaction of the side chain hydroxyl groups of Thr71 or Ser71 with the N7 atom of the guanine base. The mode of guanine binding of mutants N71T and N71S was found to be essentially identical to that of a guanosine preferential RNase NW from Nicotiana glutinosa. In particular, hydrogen bonds between the N7 atom of the guanine base and the hydroxyl groups of the amino acids at position 71 (RNase MC1 numbering) were completely conserved in three guanosine preferential enzymes, thereby indicating that the hydrogen bond may play an essential role in guanine binding in guanosine preferential RNases in the RNase T2 family. Consequently, it can be concluded that amino acids at position 71 (RNase MC1 numbering) serve as one of the determinants for substrate specificity (or preference) in the RNase T2 fimily by changing the size and shape of the B2 site.     

1H and 15N NMR investigation of the interaction of pyrimidine nucleotides with ribonuclease A

Extensive 1H and 15H NMR investigations of the nucleotide moieties capable of hydrogen bonding to ribonuclease A were carried out in order to gain more detailed information on the specificity of nucleotide-enzyme interaction. The 1H investigations focussed on those protons presumed to be involved in hydrogen bonding between the various nucleotides and the enzyme. In particular these were the imino protons of the uridine nucleotides and the amino protons of the cytidine nucleotides. The technique of 15N-1H double quantum filtering was applied for observation of the resonances of the latter in the nucleotide-enzyme complex. The downfield shift observed for the imino proton resonance of the uridine nucleotides was indicative of hydrogen bond formation to the enzyme. 15N NMR spectra of the free nucleotides and the nucleotide-enzyme complexes were also acquired to examine the possibility of hydrogen bond formation at the N3 site of both pyrimidine bases and the amino group of the cytidine nucleotides. The downfield shift observed for the 15N3 resonance of the uridine nucleotides and the upfield shift observed for the corresponding resonance of the cytidine nucleotides was evidence that the N3 moiety acts as hydrogen donor or hydrogen acceptor in the nucleotide-enzyme complex. The effect of complex formation on the 15N1 resonance of the respective bases was also studied. Both 1H and 15N NMR results indicated subtle differences between the complexes of the 2' and 3' nucleotides. The extent of hydrogen bonding as well as the arrangement of the nucleotide base at the active site of the enzyme varies in dependence on the position of the phosphate group. It is established that hydrogen bonding, though not the main binding force between the nucleotides and the enzyme, is certainly a major factor of RNase A specificity for pyrimidine nucleotides.     

Binding modes of inhibitors to ribonuclease T1 as studied by nuclear magnetic resonance

The binding modes of inhibitors to ribonuclease T1 (RNase T1) were studied by the analyses of 270-MHz proton NMR spectra. The chemical shift changes upon binding of phosphate, guanosine, 2'-GMP, 3'-GMP, 5'-GMP, and guanosine 3',5'-bis(phosphate) were observed as high field shifted methyl proton resonances of RNase T1. One methyl resonance was shifted upon binding of phosphate and guanosine nucleotides but not upon binding of guanosine. Four other methyl resonances were shifted upon binding of guanosine and guanosine nucleotides but not upon binding of phosphate. From the analyses of nuclear Overhauser effects for the pair of H8 and H1' protons, together with the vicinal coupling constants for the pair of H1' and H2' protons, the conformation of the guanosine moiety as bound to RNase T1 is found to be C3'-endo-syn for 2'-GMP and 3'-GMP and C3'-endo-anti for 5'-GMP and guanosine 3',5'-bis(phosphate). These observations suggest that RNase T1 probably has specific binding sites for the guanine base and 3'-phosphate group (P1 site) but not for the 5'-phosphate group (PO site) or the ribose ring. The weak binding of guanosine 3',5'-bis(phosphate) and 5'-GMP to RNase T1 is achieved by taking the anti form about the glycosyl bond. The productive binding to RNase T1 probably requires the syn form of the guanosine moiety of RNA substrates.     

Modes of binding of 2'-AMP to RNase T1. A computer modeling study.

The modes of binding of adenosine 2'-monophosphate (2'-AMP) to the enzyme ribonuclease (RNase) T1 were determined by computer modelling studies. The phosphate moiety of 2'-AMP binds at the primary phosphate binding site. However, adenine can occupy two distinct sites--(1) The primary base binding site where the guanine of 2'-GMP binds and (2) The subsite close to the N1 subsite for the base on the 3'-side of guanine in a guanyl dinucleotide. The minimum energy conformers corresponding to the two modes of binding of 2'-AMP to RNase T1 were found to be of nearly the same energy implying that in solution 2'-AMP binds to the enzyme in both modes. The conformation of the inhibitor and the predicted hydrogen bonding scheme for the RNase T1-2'-AMP complex in the second binding mode (S) agrees well with the reported x-ray crystallographic study. The existence of the first mode of binding explains the experimental observations that RNase T1 catalyses the hydrolysis of phosphodiester bonds adjacent to adenosine at high enzyme concentrations. A comparison of the interactions of 2'-AMP and 2'-GMP with RNase T1 reveals that Glu58 and Asn98 at the phosphate binding site and Glu46 at the base binding site preferentially stabilise the enzyme-2'-GMP complex.     

1H-NMR investigation of the interaction between RNase T1 and a novel substrate analog, 2'-deoxy-2'-fluoroguanylyl-(3'-5')uridine

The interaction between RNase T1 and a non-hydrolysable substrate analog, 2'-deoxy-2'-fluoroguanylyl-(3'-5')uridine (GfpU), was investigated using 1H-NMR spectroscopy. In the complex, the Gfp portion takes the syn form around the glycosidic bond and the 3'-endo form for the ribose moiety, similar to those found in 3'-GMP and 2'-deoxy-2'-fluoroguanosine 3'-monophosphate (Gfp). However, in contrast to the cases of these two inhibitors, the complex formation with GfpU at pH 6.0 was found to shift the His-40 C2 proton resonance of RNase T1 to high field as much as 1 ppm. At pH 6.0, this histidine residue appears to be unprotonated in the complex, but is protonated in the free enzyme (pKa of His-40 being 7.9). His-40, rather than Glu-58, is probably involved in the catalytic mechanism as a Lewis base, supporting the recent results from site-directed mutagenesis.     

Inhibition of pancreatic ribonuclease by 2'-5' and 3'-5' oligonucleotides.

Forty different oligonucleotides were investigated as possible inhibitors of the depolymerizing activity of RNase A. The strongest inhibitors among the diribonucleoside 2'-5' mono- phosphates were: G2'-5'G, C2'-5'G and U2'-5'G, and among the diribonucleoside 3'-5' monophosphates: ApU, ApC and GpU. Of the eight trinucleotides investigated, ApApUp, ApApCp and ApGpUp were the strongest inhibitors. All four dinucleotides studied (ApUp, ApCp, GpUp and GpCp) were very strong inhibitors, ApUp being the strongest one. The results show that the nature of the various bases in the oligonucleotide has an effect on the degree of inhibition, and that the 3' phosphomonoester group increases the binding of the oligonucleotide to RNase A. These inhibitors can be used in physicochemical and biochemical studies of ribonuclease.     

Raman spectroscopic study on the structure of ribonuclease F1 and the binding mode of inhibitor.

The structure of RNase F1 in aqueous solution has been studied by Raman spectroscopy and compared with that of a homologous enzyme, RNase T1. RNase F1 contains less beta-sheet and alpha-helical structure and more irregular structure than RNase T1. The strength of hydrogen bonding is weak in the beta-sheet and strong in the alpha-helix compared to that of RNase T1. Two disulfide bridges take the gauche-gauche and gauche-trans conformations, respectively. The overall hydrogen bonding of nine Tyr side chains in RNase F1 is very similar to that in RNase T1. Both of two His residues have pKa values around 8.2, which are close to those of the His residues in the active site of RNase T1. Upon binding of 2'-GMP, the hydrogen bonding of some Tyr side chains changes to a more proton-donating state. 2'-GMP is strongly hydrogen bonded with the enzyme at N7 of the guanine ring and takes the C3' endo-syn conformation. The binding mode of the inhibitor is identical to that found for RNase T1. In spite of significant differences in secondary structure, the molecular architecture of the active site seems to be highly conserved.     

The degradation of ribonucleic acid in the cotyledons of Pisum arvense

1. A ribonuclease has been partially purified from the cotyledons of germinating seed of Pisum arvense. 2. The enzyme degrades ribopolynucleotides to adenosine 3'-phosphate, guanosine 3'-phosphate and the cyclic nucleotides cytidine 2',3'-phosphate and uridine 2',3'-phosphate; no resistant ;core' remains. 3. The activity of RNA-degrading enzymes in the cotyledons increases to a maximum during the first 5 days of germination, passes through a minimum around the eighth day, and thereafter increases again. 4. Ion-exchange chromatography of methanol-soluble extracts of cotyledons revealed the presence, amongst other components, of the 2'-, 3'- and 5'-phosphates of cytidine and uridine, the 3'- and 5'-phosphates of adenosine, and guanosine 5'-phosphate. 5. Seed soaked in a solution containing [(32)P]orthophosphate gave a methanol-soluble fraction containing labelled nucleoside 5'-phosphates, but nucleoside 2'- and 3'-phosphates were not labelled. 6. It is believed that the nucleoside 2'- and 3'-phosphates arise by the action of ribonuclease on cotyledon RNA.     

Reaction of (bromoacetamido)nucleoside affinity labels with ribonuclease A: evidence for steric control of reaction specificity and alkylation rate

Four new bromoacetamido pyrimidine nucleosides have been synthesized and are affinity labels for the active site of bovine pancreatic ribonuclease A (RNase A). All bind reversibly to the enzyme and react covalently with it, resulting in inactivation. The binding constants Kb and the first-order decomposition rate constants k3 have been determined for each derivative. They are the following: 3'-(bromoacetamido)-3'-deoxyuridine, Kb = 0.062 M, k3 = 3.3 X 10(-4) s-1; 2'-(bromoacetamido)-2'-deoxyxylofuranosyluracil, Kb = 0.18 M, k3 = 1700 X 10(-4) s-1; 3'-(bromoacetamido)-3'-deoxyarabinofuranosyluracil, Kb = 0.038 M, k3 = 6.6 X 10(-4) s-1; and 3'-(bromoacetamido)-3'-deoxythymidine, Kb = 0.094 M, k3 = 2.7 X 10(-4) s-1. 3'-(Bromoacetamido)-3'-deoxyuridine reacts exclusively with the histidine-119 residue, giving 70% of a monoalkylated product substituted at N-1, 14% of a monoalkylated derivative substituted at N-3, and 16% of a dialkylated species substituted at both N-1 and N-3. Both 2'-(bromoacetamido)-2'-deoxyxylofuranosyluracil and 3'-(bromoacetamido)-3'-deoxyarabinofuranosyluracil react with absolute specificity at N-3 of the histidine-12 residue. 3'-(Bromoacetamido)-3'-deoxythymidine alkylates histidines-12 and -119. The major product formed in 57% yield is substituted at N-3 of histidine-12. A monoalkylated derivative, 8% yield, is substituted at N-1 of histidine-119. A disubstituted species is formed in 14% yield and is alkylated at both N-3 of histidine-12 and N-1 of histidine-119. A specific interaction of the "down" 2'-OH group, unique to 3'-(bromoacetamido)-3'-deoxyuridine, serves to orient the 3'-bromoacetamido residue close to the imidazole ring of histidine-119. The 2'-OH group of 3',5'-dinucleoside phosphate substrates may serve a similar role in the catalytic mechanism, allowing histidine-119 to protonate the leaving group in the transphosphorylation step. (Bromoacetamido)nucleosides are bound in the active site of RNase A in a variety of distinct conformations which are responsible for the different specificities and alkylation rates.     

Effect of 2'-5' phosphodiesters on DNA transesterification by vaccinia topoisomerase

Vaccinia topoisomerase forms a covalent DNA-(3'-phosphotyrosyl)-enzyme intermediate at a pentapyrimidine target site 5'-CCCTTp downward arrow in duplex DNA. By introducing single 2'-5' phosphodiesters in lieu of a standard 3'-5' phosphodiester linkage, we illuminate the contributions of phosphodiester connectivity to DNA transesterification. We find that the DNA cleavage reaction was slowed by more than six orders of magnitude when a 2'-5' linkage was present at the scissile phosphodiester (CCCTT(2')p downward arrow(5')A). Thus, vaccinia topoisomerase is unable to form a DNA-(2'-phosphotyrosyl)-enzyme intermediate. We hypothesize that the altered geometry of the 2'-5' phosphodiester limits the ability of the tyrosine nucleophile to attain a requisite, presumably apical orientation with respect to the 5'-OH leaving group. A 2'-5' phosphodiester located to the 3' side of the cleavage site (CCCTTp downward arrowN(2')p(5')N) reduced the rate of transesterification by a factor of 500. In contrast, 2'-5' phosphodiesters at four other sites in the scissile strand (TpCGCCCTpT downward arrowATpTpC) and five positions in the nonscissile strand (3'-GGGpApApTpApA) had no effect on transesterification rate. The DNAs containing 2'-5' phosphodiesters were protected from digestion by exonuclease III. We found that exonuclease III was consistently arrested at positions 1 and 2 nucleotides prior to the encounter of its active site with the modified 2'-5' phosphodiester and that the 2'-5' linkage itself was poorly hydrolyzed by exonuclease III.     

Modification of bovine pancreatic ribonuclease A with the site-specific reagent 4-arsono-2-nitrofluorobenzene. Spectrophotometric titration of arsononitrophenyl ribonuclease A derivatives

The 4-arsono-2-nitrophenyl chromophore can serve as a versatile spectrophotometric probe of the surface structure of proteins. Values of pK1' and pK2' for the arsonic acid ionizations are near 3 and 8, respectively, and the presence of nearby positive and negative charges produces substantial alterations in the spectral response of the probe. Changes in the extinction at the wavelength of maximum difference are 30-50% of the extinction coefficients, epsilonmax, for each ionization of the arsonic acid moiety. The titration of 41-(4-arsono-2-nitrophenyl)ribonuclease A indicates that the arsonate dianion binds near the active-site histidine residues. With protonation of a carboxylate side chain in the acidic region, presumably aspartic acid-121, the active site is disrupted. The 41-(4-arsono-2-nitrophenyl) group interacts to a greater degree with the histidine-119 side chain than it does with the histidine-12 residue. Interactions of uridine or 3'-cytidylic acid with the ligand-binding region of 41-(4-arsono-2-nitrophenyl) ribonuclease A modify the spectrophotometric response extensively. 3'-Cytidylic acid binds 41-(4-arsono-2-nitrophenyl) ribonuclease A with an affinity 300 times less than that for native ribonuclease A and 17 times lower than that for 41-(2,4-dinitrophenyl) ribonuclease A. The arsononitrophenyl chromophore is responsive to changes in the active site of ribonuclease A induced by such perturbants as ligand binding, chemical modification, and both acid and thermal denaturation.     

Substrate specificity of E. coli uridine phosphorylase. Further evidences of high-syn conformation of the substrate in uridine phosphorolysis

Twenty five uridine analogues have been tested and compared with uridine with respect to their potency to bind to E. coli uridine phosphorylase. The kinetic constants of the phosphorolysis reaction of uridine derivatives modified at 2′-, 3′- and 5′-positions of the sugar moiety and 2-, 4-, 5- and 6-positions of the heterocyclic base were determined. The absence of the 2′- or 5′-hydroxyl group is not crucial for the successful binding and phosphorolysis. On the other hand, the absence of both the 2′- and 5′-hydroxyl groups leads to the loss of substrate binding to the enzyme. The same effect was observed when the 3′-hydroxyl group is absent, thus underlining the key role of this group. Our data shed some light on the mechanism of ribo- and 2′-deoxyribonucleoside discrimination by E. coli uridine phosphorylase and E. coli thymidine phosphorylase. A comparison of the kinetic results obtained in the present study with the available X-ray structures and analysis of hydrogen bonding in the enzyme-substrate complex demonstrates that uridine adopts an unusual high-syn conformation in the active site of uridine phosphorylase.     

Analogs of (2'-5')oligo(A). Endonuclease activation and inhibition of protein synthesis in intact cells

Synthetic analogs of (2'-5')oligo(A) were assayed for endonuclease activation in cell extracts and for inhibition of protein synthesis in intact cells. The analogs are triadenylates: (i) methylated in the terminal 3'-OH; (ii) methylated at all three 3'-OH groups; (iii) with different numbers of phosphate groups at the 5' terminus or with a methylene group between the beta- and gamma-phosphate. Only 5'-phosphorylated monomethylated analogs activate an endonuclease in cell extracts and are powerful inhibitors of protein synthesis in intact cells. The analogs with only one 5'-terminal phosphate may require addition of another phosphate for activity since the kinase inhibitor 2-aminopurine prevents endonuclease activation by this compound but not by the di- and triphosphate-terminated triadenylates. These results suggest that two terminal phosphates and one or two free 3'-OH are required for endonuclease activation and inhibition of protein synthesis. The monomethylated analogs are more active than (2'-5')pppA3 because of their resistance to degradation by cellular enzymes. Accordingly, the monomethylated analogs cause a prolonged inhibition of protein synthesis in human fibroblasts treated with nanomolar concentrations of these compounds.     

Microenvironment at the substrate binding subsite of the active site of UDPglucose 4-epimerase from Kluyveromyces fragilis using a fluorescent analog of UMP.

A chromophorics and fluorescent analog of uridine 5'-monophosphate (UMP), a known competitive inhibitor of UDPglucose 4-epimerase was synthesised. This analog, namely 2',3'-O-(2,4,6-trinitrocyclohexadienylidene) uridine 5'-monophosphate, was found to be a powerful reversible inhibitor of UDPglucose 4-epimerase indicating its interaction with the substrate binding site of the enzyme. The extreme sensitivity of the fluorescence emission spectrum of this analog to solvent polarity makes it an excellent probe for the study of the environment at the active site of the enzyme. We report here the effective use of this UMP analog to demonstrate that the hydroxyl groups of the ribose moiety of UMP and presumably the substrates (UDPgalactose and UDPglucose) do not reside in a hydrophobic milieu.     

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.     

Kinetic parameters and recognition of thymidine analogues with varying functional groups by thymidine phosphorylase

Thymidine phosphorylase (TP, EC 2.4.2.4) recognized the structure of the substrate with high specificity, via both the base and the ribosyl moieties. The replacement of 3'-OH of thymidine markedly influenced its catalytic activity with TP. The conversion of pyrimidine nucleosides with modified base moieties to the corresponding 1-phosphate form was poor. The leaving group activity decreased with an increase in aromaticity of the pyrimidine base moiety, because of increased difficulty in polarizing the base by the amino acids local to the active site. The replacement of 3' and 5' functional groups tended to decrease the reaction rate and the percentage conversion with TP. In particular the ribosyl 3' hydroxyl group was structurally important for the binding of the substrate by the enzyme. The kinetic assay clearly showed high K(m) and low V(max) values on replacing the 3' hydroxyl group with hydrogen.     

Rare earth metal ions for unprecedentedly fast RNA hydrolysis.

Adenylyl(3'-5')adenosine (ApA) and uridyl(3'-5')uridine (UpU) are hydrolyzed at unprecedentedly large rates by rare earth metal ions at pH 8, 30 degrees C. With 0.01 M Tm(III), the half-lives are 10 min and 51 min, respectively. Potentiality of these ions as catalytic center of artificial ribonuclease is proposed.     

3-Ribosyl-6-methyluracil as a phosphate acceptor in the synthesis of the internucleotide bond catalyzed by pancreatic ribonuclease.

The synthesis of uridylyl-(3'-5')-3-ribosyl-6-methyluracil (UprmU) catalyzed by pancreatic ribonuclease (EC 3.4.1.22) has been performed using uridine 2', 3'-cyclic phosphate (U greater than p) as phosphate donor and 3-ribosyl-6-methyluracil (rmU) as phosphate acceptor. The rate of synthesis of UprmU is much higher than that of uridylyl-(3'-5')-uridine (UpU) in a control experiment under the same conditions with uridine as acceptor. The yields of UpU and UprmU were 20 and 17% respectively. The competitive hydrolysis of the initial U greater than p also proceeds faster when rmU is used as the acceptor. The relationship between the conformation of this nucleoside and its acceptor activity in the enzymatic synthesis of the internucleotide bond is discussed.     

Crystallographic structure of the nuclease domain of 3'hExo, a DEDDh family member, bound to rAMP

A human 3'-5'-exoribonuclease (3'hExo) has recently been identified and shown to be responsible for histone mRNA degradation. Functionally, 3'hExo and a stem-loop binding protein (SLBP) target opposite faces of a unique highly conserved stem-loop RNA scaffold towards the 3' end of histone mRNA, which is composed of a 6 bp stem and a 4 nt loop, followed by an ACCCA sequence. Its Caenorhabditis elegans homologue, ERI-1, has been shown to degrade small interfering RNA in vitro and to function as a negative regulator of RNA interference in neuronal cells. We have determined the structure of the nuclease domain (Nuc) of 3'hExo complexed with rAMP in the presence of Mg2+ at 1.6 A resolution. The Nuc domain adopts an alpha/beta globular fold, with four acidic residues coordinating a binuclear metal cluster within the active site, whose topology is related to DEDDh exonuclease family members, despite a very low level of primary sequence identity. The two magnesium cations in the Nuc active site are coordinated to D134, E136, D234 and D298, and together with H293, which can potentially act as a general base, provide a platform for hydrolytic cleavage of bound RNA in the 3' --> 5' direction. The bound rAMP is positioned within a deep active-site pocket, with its purine ring close-packed with the hydrophobic F185 and L189 side-chains and its sugar 2'-OH and 3'-OH groups hydrogen bonded to backbone atoms of Nuc. There are striking similarities between the active sites of Nuc and epsilon186, an Escherichia coli DNA polymerase III proofreading domain, providing a common hydrolytic cleavage mechanism for RNA degradation and DNA editing, respectively.