Divalent metal ions promote the formation of the 5'-splice site recognition complex in a self-splicing group II intron

Group II introns are ribozymes occurring in genes of plants, fungi, lower eukaryotes, and bacteria. These large RNA molecular machines, ranging in length from 400 to 2500 nucleotides, are able to catalyze their own excision from pre-mRNA, as well as to reinsert themselves into RNA or sometimes even DNA. The intronic domain 1 contains two sequences (exon binding sites 1 and 2, EBS1 and EBS2) that pair with their complementary regions at the 3′-end of the 5′-exon (intron binding sites 1 and 2, IBS1 and IBS2) such defining the 5′-splice site. The correct recognition of the 5′-splice site stands at the beginning of the two steps of splicing and is thus crucial for catalysis. It is known that metal ions play an important role in folding and catalysis of ribozymes in general. Here, we characterize the specific metal ion requirements for the formation of the 5′-splice site recognition complex from the mitochondrial yeast group II intron Sc.ai5γ. Circular dichroism studies reveal that the formation of the EBS1 · IBS1 duplex does not necessarily require divalent metal ions, as large amounts of monovalent metal ions also promote the duplex, albeit at a 5000 times higher concentration. Nevertheless, micromolar amounts of divalent metal ions, e.g. Mg²⁺ or Cd²⁺, strongly promote the formation of the 5′-splice site. These observations illustrate that a high charge density independent of the nature of the ion is needed for binding EBS1 to IBS1, but divalent metal ions are presumably the better players.     

Lead cleavage sites in the core structure of group I intron-RNA.

Self-splicing of group I introns requires divalent metal ions to promote catalysis as well as for the correct folding of the RNA. Lead cleavage has been used to probe the intron RNA for divalent metal ion binding sites. In the conserved core of the intron, only two sites of Pb2+ cleavage have been detected, which are located close to the substrate binding sites in the junction J8/7 and at the bulged nucleotide in the P7 stem. Both lead cleavages can be inhibited by high concentrations of Mg2+ and Mn2+ ions, suggesting that they displace Pb2+ ions from the binding sites. The RNA is protected from lead cleavage by 2'-deoxyGTP, a competitive inhibitor of splicing. The two major lead induced cleavages are both located in the conserved core of the intron and at phosphates, which had independently been demonstrated to interact with magnesium ions and to be essential for splicing. Thus, we suggest that the conditions required for lead cleavage occur mainly at those sites, where divalent ions bind that are functionally involved in catalysis. We propose lead cleavage analysis of functional RNA to be a useful tool for mapping functional magnesium ion binding sites.     

Mapping divalent metal ion binding sites in a group II intron by Mn(2+)- and Zn(2+)-induced site-specific RNA cleavage.

The function of group II introns depends on positively charged divalent metal ions that stabilize the ribozyme structure and may be directly involved in catalysis. We investigated Mn2+- and Zn2+-induced site-specific RNA cleavage to identify metal ions that fit into binding pockets within the structurally conserved bI1 group II intron domains (DI-DVI), which might fulfill essential roles in intron function. Ten cleavage sites were identified in DI, two sites in DIII and two in DVI. All cleavage sites are located in the center or close to single-stranded and flexible RNA structures. Strand scissions mediated by Mn2+/Zn2+ are competed for by Mg2+, indicating the existence of Mg2+ binding pockets in physical proximity to the observed Mn2+-/Zn2+-induced cleavage positions. To distinguish between metal ions with a role in structure stabilization and those that play a more specific and critical role in the catalytic process of intron splicing, we combined structural and functional assays, comparing wild-type precursor and multiple splicing-deficient mutants. We identified six regions with binding pockets for Mg2+ ions presumably playing an important role in bI1 structure stabilization. Remarkably, assays with DI deletions and branch point mutants revealed the existence of one Mg2+ binding pocket near the branching A, which is involved in first-step catalysis. This pocket formation depends on precise interaction between the branching nucleotide and the 5' splice site, but does not require exon-binding site 1/intron binding site 1 interaction. This Mg2+ ion might support the correct placing of the branching A into the 'first-step active site'.     

Mapping metal-binding sites in the catalytic domain of bacterial RNase P RNA

Ribonuclease P (RNase P) is a ribonucleoprotein enzyme that contains a universally conserved, catalytically active RNA component. RNase P RNA requires divalent metal ions for folding, substrate binding, and catalysis. Despite recent advances in understanding the structure of RNase P RNA, no comprehensive analysis of metal-binding sites has been reported, in part due to the poor crystallization properties of this large RNA. We have developed an abbreviated yet still catalytic construct, Bst P7Δ RNA, which contains the catalytic domain of the bacterial RNase P RNA and has improved crystallization properties. We use this mutant RNA as well as the native RNA to map metal-binding sites in the catalytic core of the bacterial RNase P RNA, by anomalous scattering in diffraction analysis. The results provide insight into the interplay between RNA structure and focalization of metal ions, and a structural basis for some previous biochemical observations with RNase P. We use electrostatic calculations to extract the potential functional significance of these metal-binding sites with respect to binding Mg²⁺. The results suggest that with at least one important exception of specific binding, these sites mainly map areas of diffuse association of magnesium ions.     

Essential roles of innersphere metal ions for the formation of the glutamine binding site in a bifunctional ribozyme.

Numerous studies on naturally occurring ribozymes have shown that the functional roles of metal ions in promoting RNA catalysis are diverse. Earlier studies performed on the in vitro selected aminoacyl-transferase ribozyme (ATRib) have revealed that a fully hydrated Mg2+ ion plays an essential role in catalysis [Suga, H., Cowan, J. A., and Szostak, J. W. (1998) Biochemistry 28, 10118-10125]. More recently, we have evolved this ATRib into a bifunctional ribozyme, called AD02 [Lee, N., et al. (2000) Nat. Struct. Biol. 7, 28-33]. This new ribozyme consists of two catalytic domains, the original ATRib domain and a new glutamine-recognition (QR) domain, and exhibits a function of charging glutamine to tRNA. Here we elucidate crucial roles of metal ions involved in the QR domain, that are distinct from those in the ATRib domain. The metal ions in the QR domain require innersphere coordinations, and both Mg2+ and Ca2+ can support catalysis. Extensive Tb3+-Mg2+ and Tb3+-Co(NH3)6(3+) competition cleavage experiments have shown that the QR domain has high and low affinity metal binding sites, which are involved in the Mg2+-dependent structural alteration to form the glutamine binding site [Lee, N., and Suga, H. (2001) RNA 7, 1043-1051]. Kinetic studies in the presence of divalent and monovalent ions have suggested that the essential role of the metal ions in the QR domain is most likely structural.     

Monitoring the structure of Escherichia coli RNase P RNA in the presence of various divalent metal ions

Lead(II)-induced cleavage can be used as a tool to probe conformational changes in RNA. In this report, we have investigated the conformation of M1 RNA, the catalytic subunit of Escherichia coli RNase P, by studying the lead(II)-induced cleavage pattern in the presence of various divalent metal ions. Our data suggest that the overall conformation of M1 RNA is very similar in the presence of Mg(2+), Mn(2+), Ca(2+), Sr(2+) and Ba(2+), while it is changed compared to the Mg(2+)-induced conformation in the presence of other divalent metal ions, Cd(2+) for example. We also observed that correct folding of some M1 RNA domains is promoted by Pb(2+), while folding of other domain(s) requires the additional presence of other divalent metal ions, cobalt(III) hexamine or spermidine. Based on the suppression of Pb(2+) cleavage at increasing concentrations of various divalent metal ions, our findings suggest that different divalent metal ions bind with different affinities to M1 RNA as well as to an RNase P hairpin-loop substrate and yeast tRNA(Phe). We suggest that this approach can be used to obtain information about the relative binding strength for different divalent metal ions to RNA in general, as well as to specific RNA divalent metal ion binding sites. Of those studied in this report, Mn(2+) is generally among the strongest RNA binders.     

Metal-ion-dependent catalysis and specificity of CCA-adding enzymes: a comparison of two classes

The CCA-adding enzymes [ATP(CTP):tRNA nucleotidyl transferases] catalyze synthesis of the conserved and essential CCA sequence to the tRNA 3' end. These enzymes are divided into two classes of distinct structures that differ in the overall orientation of the head to tail domains. However, the catalytic core of the two classes is conserved and contains three carboxylates in a geometry commonly found in DNA and RNA polymerases that use the two-metal-ion mechanism for phosphoryl transfer. Two important aspects of the two-metal-ion mechanism are tested here for CCA enzymes: the dependence on metal ions for catalysis and for specificity of nucleotide addition. Using the archaeal Sulfolobus shibabae enzyme as an example of the class I, and the bacterial Escherichia coli enzyme as an example of the class II, we show that both enzymes depend on metal ions for catalysis, and that both use primarily Mg2+ and Mn2+ as the "productive" metal ions, but several other metal ions such as Ca2+ as the "nonproductive" metal ions. Of the two productive metal ions, Mg2+ specifically promotes synthesis of the correct CCA, whereas Mn2+ preferentially accelerates synthesis of the noncognate CCC and poly(C). Thus, despite evolution of structural diversity of two classes, both classes use metal ions to determine catalysis and specificity. These results provide critical insights into the catalytic mechanism of CCA synthesis to allow the two classes to be related to each other, and to members of the larger family of DNA and RNA polymerases.     

Synthetic metallonucleases for RNA cleavage

Synthetic metallonucleases are versatile metal ion catalysts that use multiple catalytic strategies for the cleavage of RNA. Recent work in the design of more active metallonucleases combines a single metal ion with functional groups that interact with RNA, including amino acid fragments or additional metal ions. Rate enhancements by multifunctional catalysts for cleavage of simple model substrates with good leaving groups are as high as 10(6) but somewhat lower (10(5)) for real RNA. However, cleavage of RNA substrates is complicated by different binding modes and steric interactions that can interfere with catalysis. Antisense oligonucleotides, peptides and small molecules that act as RNA recognition agents increase the strength of substrate binding, but not necessarily the catalytic rate constant. In general, catalytic strategies used by synthetic metallonucleases are probably not optimized. A better grasp of the mechanism of RNA cleavage by metal ions and more effort on positioning the metal ion complex with respect to the cleavage site may lead to improved catalysts.     

Terbium-mediated footprinting probes a catalytic conformational switch in the antigenomic hepatitis delta virus ribozyme

The two forms of the hepatitis delta virus ribozyme are derived from the genomic and antigenomic RNA strands of the human hepatitis delta virus (HDV), where they serve a crucial role in pathogen replication by catalyzing site-specific self-cleavage reactions. The HDV ribozyme requires divalent metal ions for formation of its tertiary structure, consisting of a tight double-nested pseudoknot, and for efficient self- (or cis-) cleavage. Comparison of recently solved crystal structures of the cleavage precursor and 3' product indicates that a significant conformational switch is required for catalysis by the genomic HDV ribozyme. Here, we have used the lanthanide metal ion terbium(III) to footprint the precursor and product solution structures of the cis-acting antigenomic HDV ribozyme. Inhibitory Tb(3+) binds with high affinity to similar sites on RNA as Mg(2+) and subsequently promotes slow backbone scission. We find subtle, yet significant differences in the terbium(III) footprinting pattern between the precursor and product forms of the antigenomic HDV ribozyme, consistent with differences in conformation as observed in the crystal structures of the genomic ribozyme. In addition, UV melting profiles provide evidence for a less tight tertiary structure in the precursor. In both the precursor and product we observe high-affinity terbium(III) binding sites in joining sequence J4/2 (Tb(1/2) approximately 4 microM) and loop L3, which are key structural components forming the catalytic core of the HDV ribozyme, as well as in several single-stranded regions such as J1/2 and the L4 tetraloop (Tb(1/2) approximately 50 microM). Sensitized luminescence spectroscopy confirms that there are at least two affinity classes of Tb(3+) binding sites. Our results thus demonstrate that a significant conformational change accompanies catalysis in the antigenomic HDV ribozyme in solution, similar to the catalytic conformational switch observed in crystals of the genomic form, and that structural and perhaps catalytic metal ions bind close to the catalytic core.     

Metal ion requirements for sequence-specific endoribonuclease activity of the Tetrahymena ribozyme

A shortened form of the self-splicing intervening sequence RNA of Tetrahymena thermophila acts as an enzyme, catalyzing sequence-specific cleavage of RNA substrates. We have now examined the metal ion requirements of this reaction. Mg2+ and Mn2+ are the only metal ions that by themselves give RNA enzyme activity. Atomic absorption spectroscopy indicates that Zn, Cu, Co, and Fe are not present in amounts equimolar to the RNA enzyme and when added to reaction mixtures do not facilitate cleavage. Thus, these ions can be eliminated as cofactors for the reaction. While Ca2+ has no activity by itself, it alleviates a portion of the Mg2+ requirement; 1 mM Ca2+ reduces the Mg2+ optimum from 2 to 1 mM. These results, combined with studies of the reactivity of mixtures of metal ions, lead us to postulate that two classes of metal ion binding sites are required for catalysis. Class 1 sites have more activity with Mn2+ than with Mg2+, with the other divalent ions and Na+ and K+ having no activity. It is not known if ions located at class 1 sites have specific structural roles or are directly involved in active-site chemistry. Class 2 sites, which are presumably structural, have an order of preference Mg2+ greater than or equal to Ca2+ greater than Mn2+ and Ca2+ greater than Sr2+ greater than Ba2+, with Zn2+, Cu2+, Co2+, Na+, and K+ giving no detectable activity over the concentration range tested.     

The affinity of magnesium binding sites in the Bacillus subtilis RNase P x pre-tRNA complex is enhanced by the protein subunit

The RNA subunit of bacterial ribonuclease P (RNase P) requires high concentrations of magnesium ions for efficient catalysis of tRNA 5'-maturation in vitro. The protein component of RNase P, required for cleavage of precursor tRNA in vivo, enhances pre-tRNA binding by directly contacting the 5'-leader sequence. Using a combination of transient kinetics and equilibrium binding measurements, we now demonstrate that the protein component of RNase P also facilitates catalysis by specifically increasing the affinities of magnesium ions bound to the RNase P x pre-tRNA(Asp) complex. The protein component does not alter the number or apparent affinity of magnesium ions that are either diffusely associated with the RNase P RNA polyanion or required for binding mature tRNA(Asp). Nor does the protein component alter the pH dependence of pre-tRNA(Asp) cleavage catalyzed by RNase P, providing further evidence that the protein component does not directly stabilize the catalytic transition state. However, the protein subunit does increase the affinities of at least four magnesium sites that stabilize pre-tRNA binding and, possibly, catalysis. Furthermore, this stabilizing effect is coupled to the P protein/5'-leader contact in the RNase P holoenzyme x pre-tRNA complex. These results suggest that the protein component enhances the magnesium affinity of the RNase P x pre-tRNA complex indirectly by binding and positioning pre-tRNA. Furthermore, RNase P is inhibited by cobalt hexammine (K(I) = 0.11 +/- 0.01 mM) while magnesium, manganese, cobalt, and zinc compete with cobalt hexammine to activate RNase P. These data are consistent with the hypothesis that catalysis by RNase P requires at least one metal-water ligand or one inner-sphere metal contact.     

Conservation of helical structure contributes to functional metal ion interactions in the catalytic domain of ribonuclease P RNA

Like protein enzymes, catalytic RNAs contain conserved structure motifs important for function. A universal feature of the catalytic domain of ribonuclease P RNA is a bulged-helix motif within the P1-P4 helix junction. Here, we show that changes in bulged nucleotide identity and position within helix P4 affect both catalysis and substrate binding, while a subset of the mutations resulted only in catalytic defects. We find that the proximity of the bulge to sites of metal ion coordination in P4 is important for catalysis; moving the bulge distal to these sites and deleting it had similarly large effects, while moving it proximal to these sites had only a moderate effect on catalysis. To test whether the effects of the mutations are linked to metal ion interactions, we used terbium-dependent cleavage of the phosphate backbone to probe metal ion-binding sites in the wild-type and mutant ribozymes. We detect cleavages at specific sites within the catalytic domain, including helix P4 and J3/4, which have previously been shown to participate directly in metal ion interactions. Mutations introduced into P4 cause local changes in the terbium cleavage pattern due to alternate metal ion-binding configurations with the helix. In addition, a bulge deletion mutation results in a 100-fold decrease in the single turnover cleavage rate constant at saturating magnesium levels, and a reduced affinity for magnesium ions important for catalysis. In light of the alternate terbium cleavage pattern in P4 caused by bulge deletion, this decreased ability to utilize magnesium ions for catalysis appears to be due to localized structural changes in the ribozyme's catalytic core that weaken metal ion interactions in P4 and J3/4. The information reported here, therefore, provides evidence that the universal conservation of the P4 structure is based in part on optimization of metal ion interactions important for catalysis.     

Metal ions in the structure and function of RNA

It is becoming increasingly clear that RNA is more than a passive carrier of genetic information. Folded RNA molecules play key roles in almost every aspect of cellular metabolism, including protein transport, RNA splicing, peptide bond formation, and translational regulation. This is facilitated by the multifunctional nature of RNA biopolymers which can serve as rigid structural scaffolds, conformational switches, and catalysts for chemical reactions. In all cases, metal ions play a crucial role in RNA function. For folded RNA molecules, the pathway for adopting proper tertiary structure, and the stabilization of that structure, depends on specific and nonspecific interactions with certain classes of metal ions. There is a rapidly expanding repertoire of RNA structural motifs that typically sequester metal ions, and these are being studied using new spectroscopic and chemical methodologies. Many ribozymes (catalytic RNA molecules) depend on metal ions as cofactors that are explicitly involved in the chemical mechanism of catalysis. All of these functions are exemplified by recent studies of group II introns, which are among the largest ribozymes found in Nature. In this case, there are specific roles for metal ions in the folding pathway, the tertiary structure and the chemical mechanism.     

Metal ion probing of rRNAs: evidence for evolutionarily conserved divalent cation binding pockets.

Ribosomes are multifunctional RNP complexes whose catalytic activities absolutely depend on divalent metal ions. It is assumed that structurally and functionally important metal ions are coordinated to highly ordered RNA structures that form metal ion binding pockets. One potent tool to identify the structural surroundings of high-affinity metal ion binding pockets is metal ion-induced cleavage of RNA. Exposure of ribosomes to divalent metal ions, such as Pb2+, Mg2+, Mn2+, and Ca2+, resulted in site-specific cleavage of rRNAs. Sites of strand scission catalyzed by different cations accumulate at distinct positions, indicating the existence of general metal ion binding centers in the highly folded rRNAs in close proximity to the cleavage sites. Two of the most efficient cleavage sites are located in the 5' domain of both 23S and 16S rRNA, regions that are known to self-fold even in the absence of ribosomal proteins. Some of the efficient cleavage sites were mapped to the peptidyl transferase center located in the large ribosomal subunit. Furthermore, one of these cleavages was clearly diminished upon AcPhe-tRNA binding to the P site, but was not affected by uncharged tRNA. This provides evidence for a close physical proximity of a metal ion to the amino acid moiety of charged tRNAs. Interestingly, comparison of the metal ion cleavage pattern of eubacterial 70S with that of human 80S ribosomes showed that certain cleavage sites are evolutionarily highly conserved, thus demonstrating an identical location of a nearby metal ion. This suggests that cations, bound to evolutionarily constrained binding sites, are reasonable candidates for being of structural or functional importance.     

Functional identification of ligands for a catalytic metal ion in group I introns

Many enzymes use metal ions within their active sites to achieve enormous rate acceleration. Understanding how metal ions mediate catalysis requires elucidation of metal ion interactions with both the enzyme and the substrate(s). The three-dimensional arrangement determined by X-ray crystallography provides a powerful starting point for identifying ground state interactions, but only functional studies can establish and interrogate transition state interactions. The Tetrahymena group I ribozyme is a paradigm for the study of RNA catalysis, and previous work using atomic mutagenesis and quantitative analysis of metal ion rescue behavior identified catalytic metal ions making five contacts with the substrate atoms. Here, we have combined atomic mutagenesis with site-specific phosphorothioate substitutions in the ribozyme backbone to establish transition state ligands on the ribozyme for one of the catalytic metal ions, referred to as M A. We identified the pro-S P oxygen atoms at nucleotides C208, A304, and A306 as ground state ligands for M A, verifying interactions suggested by the Azoarcus crystal structures. We further established that these interactions are present in the chemical transition state, a conclusion that requires functional studies, such as those carried out herein. Elucidating these active site connections is a crucial step toward an in-depth understanding of how specific structural features of the group I intron lead to catalysis.     

Identification of the magnesium ion binding site in the catalytic center of Escherichia coli primase by iron cleavage

Magnesium is essential for the catalysis reaction of Escherichia coli primase, the enzyme synthesizing primer RNA chains for initiation of DNA replication. To map the Mg(2+) binding site in the catalytic center of primase, we have employed the iron cleavage method in which the native bound Mg(2+) ions were replaced with Fe(2+) ions and the protein was then cleaved in the vicinity of the metal binding site by adding DTT which generated free hydroxyl radicals from the bound iron. Three Fe(2+) cleavages were generated at sites designated I, II, and III. Adding Mg(2+) or Mn(2+) ions to the reaction strongly inhibited Fe(2+) cleavage; however, adding Ca(2+) or Ba(2+) ions had much less effect. Mapping by chemical cleavage and subsequent site-directed mutagensis demonstrated that three acidic residues, Asp345 and Asp347 of a conserved DPD sequence and Asp269 of a conserved EGYMD sequence, were the amino acid residues that chelated Mg(2+) ions in the catalytic center of primase. Cleavage data suggested that binding to D345 is significantly stronger than to D347 and somewhat stronger than to D269.     

Divalent metal ion binding to a conserved wobble pair defining the upstream site of cleavage of group I self-splicing introns.

The upstream site of cleavage of all group I self-splicing introns is identified by an absolutely conserved U.G base pair. Although a wobble C.A pair can substitute the U.G pair, all other combinations of nucleotides at this position abolish splicing, suggesting that it is an unusual RNA structure, rather than sequence, that is recognized by the catalytic intron core. RNA enzymes are metalloenzymes, and divalent metal ion binding may be an important requirement for splice site recognition and catalysis. The paramagnetic broadening of NMR resonances upon manganese binding at specific sites was used to probe the interaction between divalent metal ions and an oligonucleotide model of a group I intron ribozyme substrate. Unlike previous studies in which only imino proton resonances were monitored, we have used isotopically labelled RNA and a set of complete spectral assignments to identify the location of the divalent metal binding site with much greater detail than previously possible. Two independent metal binding sites were identified for this oligonucleotide. A first metal binding site is located in the major groove of the three consecutive G.C base pairs at the end of double helical stem. A second site is found in the major groove of the RNA double helix in the vicinity of the U.G base pair. These results suggest that metal ion coordination (or a metal bridge) and tertiary interactions identified biochemically, may be used by group I intron ribozymes for substrate recognition.     

The effect of Ni(II) on DNA replication

The cellular regulation of DNA replication is governed in part by the availability of essential metal ions. A continuous supply of Mg(II) ions is necessary for the efficient and faithful replication of parental strands during S-phase as well as during the repair of DNA damage. A metal ion such as Ni(II) may interfere with the replication process by binding to sites on proteins at which essential ions normally bind. Binding at these sites by a toxic metal ion may produce inappropriate responses from the replication proteins and thus alter the normal balance in one or more of the microsteps comprising DNA synthesis. We have studied the effect of Ni(II) on DNA replication in a reconstituted in vitro system using a HeLa cell extract as a source of polymerase activity on a template of activated calf thymus DNA. Ni(II) has an initial stimulatory effect that is followed by an overall inhibition of the incorporation of DNA precursors. These results suggest that Ni(II), similar to Mg(II) may have more than one binding site, but that the binding of Ni(II) to replication proteins may significantly alter the timing of events in DNA synthesis.     

Effect of metal ion binding on the structural stability of the hepatitis C virus RNA polymerase

The RNA polymerase activity of the hepatitis C virus, a major human pathogen, has previously been shown to be supported by metal ions. In the present study, we report a systematic analysis of the effect of metal ion binding on the structural stability of the hepatitis C virus RNA polymerase. Chemical and thermal denaturation assays revealed that the stability of the protein is increased significantly in the presence of metal ions. Structural analyses clearly established that metal ion binding increases hydrophobic exposure on the RNA polymerase surface. Furthermore, our denaturation studies, coupled with polymerization assays, demonstrate that the active site region of the polymerase is more sensitive to chemical denaturant than other structural scaffolds. We also report the first detailed study of the thermodynamic parameters involved in the interaction between the hepatitis C virus RNA polymerase and metal ions. Finally, a mutational analysis was also performed to investigate the importance of Asp(220), Asp(318), and Asp(319) for metal ion binding. This mutational study underscores a strict requirement for each of the residues for metal binding, indicating that the active center of the HCV RNA polymerase is intolerant to virtually any perturbations of the metal coordination sphere, thereby highlighting the critical role of the enzyme-bound metal ions. Overall, our results indicate that metal ions play a dual modulatory role in the RNA polymerase reaction by promoting both a favorable geometry of the active site for catalysis and by increasing the structural stability of the enzyme.     

Identification of the active site of poly(A)-specific ribonuclease by site-directed mutagenesis and Fe(2+)-mediated cleavage.

Poly(A)-specific ribonuclease (PARN) is the only mammalian exoribonuclease characterized thus far with high specificity for degrading the mRNA poly(A) tail. PARN belongs to the RNase D family of nucleases, a family characterized by the presence of four conserved acidic amino acid residues. Here, we show by site-directed mutagenesis that these residues of human PARN, i.e. Asp(28), Glu(30), Asp(292), and Asp(382), are essential for catalysis but are not required for stabilization of the PARN x RNA substrate complex. We have used iron(II)-induced hydroxyl radical cleavage to map Fe(2+) binding sites in PARN. Two Fe(2+) binding sites were identified, and three of the conserved acidic amino acid residues were important for Fe(2+) binding at these sites. Furthermore, we show that the apparent dissociation constant ((app)K(d)) values for Fe(2+) binding at both sites were affected in PARN polypeptides in which the conserved acidic amino acid residues were substituted to alanine. This suggests that these residues coordinate divalent metal ions. We conclude that the four conserved acidic amino acids are essential residues of the PARN active site and that the active site of PARN functionally and structurally resembles the active site for 3'-exonuclease domain of Escherichia coli DNA polymerase I.