Role of an active site adenine in hairpin ribozyme catalysis

The hairpin ribozyme is a small catalytic RNA that accelerates reversible cleavage of a phosphodiester bond. Structural and mechanistic studies suggest that divalent metals stabilize the functional structure but do not participate directly in catalysis. Instead, two active site nucleobases, G8 and A38, appear to participate in catalytic chemistry. The features of A38 that are important for active site structure and chemistry were investigated by comparing cleavage and ligation reactions of ribozyme variants with A38 modifications. An abasic substitution of A38 reduced cleavage and ligation activity by 14,000-fold and 370,000-fold, respectively, highlighting the critical role of this nucleobase in ribozyme function. Cleavage and ligation activity of unmodified ribozymes increased with increasing pH, evidence that deprotonation of some functional group with an apparent pK(a) value near 6 is important for activity. The pH-dependent transition in activity shifted by several pH units in the basic direction when A38 was substituted with an abasic residue, or with nucleobase analogs with very high or low pK(a) values that are expected to retain the same protonation state throughout the experimental pH range. Certain exogenous nucleobases that share the amidine group of adenine restored activity to abasic ribozyme variants that lack A38. The pH dependence of chemical rescue reactions also changed according to the intrinsic basicity of the rescuing nucleobase, providing further evidence that the protonation state of the N1 position of purine analogs is important for rescue activity. These results are consistent with models of the hairpin ribozyme catalytic mechanism in which interactions with A38 provide electrostatic stabilization to the transition state.     

The role of metal ions in RNA catalysis

Understanding the catalytic mechanisms of RNA enzymes remains an important and intriguing challenge - one that has grown in importance since the recent demonstration that the ribosome is a ribozyme. At first, it seemed that all RNA enzymes compensate for the limited chemical versatility of ribonucleotide functional groups by recruiting obligatory metal ion cofactors to carry out catalytic chemistry. Mechanistic studies of the large self-splicing and pre-tRNA-processing ribozymes continue to support this idea, yielding increasingly detailed views of RNA active sites as scaffolds for positioning catalytic metal ions. Re-evaluation of the methodologies used to distinguish catalytic and structural roles for metal ions, however, has challenged this notion in the case of the small self-cleaving RNAs. Recent studies of the small ribozymes blur the distinction between catalytic and structural roles for metal ions, and suggest that RNA nucleobases have a previously unrecognized capacity for mediating catalytic chemistry.     

Purine Biosynthetic Intermediate-Containing Ribose-Phosphate Polymers as Evolutionary Precursors to RNA

The RNA world hypothesis proposes that RNA once functioned as the principal genetic material and biological catalyst. However, RNA is a complex molecule made up of phosphate, ribose, and nucleobase moieties, and its evolution is unclear. Yakhnin has proposed a period of prebiotic chemical evolution prior to the advent of replication and Darwinian evolution, in which macromolecules containing polyols joined by phosphodiester linkages underwent spontaneous transesterification reactions with selection for stability. Although he proposes that the nucleobases were obtained during this stage from less stable macromolecules, the ultimate source of the nucleobases is not addressed. We propose that the purine nucleobases arose in situ from simpler precursors attached to a ribose-phosphate backbone, and that the weaker and less specific intra- and interstrand interactions between these precursors were the forerunners to the base pairing and base stacking interactions of the modern RNA nucleobases. Further, in line with Granick’s hypothesis of biosynthetic pathways recapitulating evolution, we propose that these simpler precursors were the same or similar to intermediates of the modern de novo purine biosynthetic pathway. We propose that successive nucleobase precursors formed progressively stronger interactions that stabilized the ribose-phosphate polymer, and that the increased stability of the parent polymer drove the selection and further chemical evolution of the purine nucleobases. Such interactions may have included hydrogen bonding between ribose hydroxyls, hydrogen bonding between carbonyl oxygens and protonated amine side groups, the intra- and interstrand coordination of metal cations, and the stacking of imidazole rings. Five of the eleven steps of the modern de novo purine biosynthetic pathway have previously been shown to have alternative nonenzymatic syntheses, while a sixth step has also been proposed to occur nonenzymatically, supporting a prebiotic origin for the pathway.     

Understanding the transition states of phosphodiester bond cleavage: insights from heavy atom isotope effects

The nucleotides of DNA and RNA are joined by phosphodiester linkages whose synthesis and hydrolysis are catalyzed by numerous essential enzymes. Two prominent mechanisms have been proposed for RNA and protein enzyme catalyzed cleavage of phosphodiester bonds in RNA: (a) intramolecular nucleophilic attack by the 2'-hydroxyl group adjacent to the reactive phosphate; and (b) intermolecular nucleophilic attack by hydroxide, or other oxyanion. The general features of these two mechanisms have been established by physical organic chemical analyses; however, a more detailed understanding of the transition states of these reactions is emerging from recent kinetic isotope effect (KIE) studies. The recent data show interesting differences between the chemical mechanisms and transition state structures of the inter- and intramolecular reactions, as well as provide information on the impact of metal ion, acid, and base catalysis on these mechanisms. Importantly, recent nonenzymatic model studies show that interactions with divalent metal ions, an important feature of many phosphodiesterase active sites, can influence both the mechanism and transition state structure of nonenzymatic phosphodiester cleavage. Such detailed investigations are important because they mimic catalytic strategies employed by both RNA and protein phosphodiesterases, and so set the stage for explorations of enzyme-catalyzed transition states. Application of KIE analyses for this class of enzymes is just beginning, and several important technical challenges remain to be overcome. Nonetheless, such studies hold great promise since they will provide novel insights into the role of metal ions and other active site interactions.     

Catalytic effects of Murchison Material: Prebiotic Synthesis and Degradation of RNA Precursors

Mineral components of the Murchison meteorite were investigated in terms of potential catalytic effects on synthetic and hydrolytic reactions related to ribonucleic acid. We found that the mineral surfaces catalyzed condensation reactions of formamide to form carboxylic acids, amino acids, nucleobases and sugar precursors. These results suggest that formamide condensation reactions in the parent bodies of carbonaceous meteorites could give rise to multiple organic compounds thought to be required for the emergence of life. Previous studies have demonstrated similar catalytic effects for mineral assemblies likely to have been present in the early Earth environment. The minerals had little or no effect in promoting hydrolysis of RNA (24mer of polyadenylic acid) at 80°C over a pH range from 4.2 to 9.3. RNA was most stable in the neutral pH range, with a half-life ~5 h, but at higher and lower pH ranges the half-life decreased to ~1 h. These results suggest that if RNA was somehow incorporated into a primitive form of RNA-based thermophilic life, either it must be protected from random hydrolytic events, or the rate of synthesis must exceed the rate of hydrolysis.     

Nucleobase catalysis in the hairpin ribozyme

RNA catalysis is important in the processing and translation of RNA molecules, yet the mechanisms of catalysis are still unclear in most cases. We have studied the role of nucleobase catalysis in the hairpin ribozyme, where the scissile phosphate is juxtaposed between guanine and adenine bases. We show that a modified ribozyme in which guanine 8 has been substituted by an imidazole base is active in both cleavage and ligation, with ligation rates 10-fold faster than cleavage. The rates of both reactions exhibit bell-shaped dependence on pH, with pK(a) values of 5.7 +/- 0.1 and 7.7 +/- 0.1 for cleavage and 6.1 +/- 0.3 and 6.9 +/- 0.3 for ligation. The data provide good evidence for general acid-base catalysis by the nucleobases.     

Diverse roles of metal ions in acyl-transferase ribozymes

The dependence on metal ions for catalysis is one of the hallmark characteristics of ribozymes. Yet despite this universal reliance, the functional role of divalent ions in promoting RNA catalysis is manifold. In this study we elucidate some different roles metal ions play as catalytic cofactors, by comparing two functionally co-evolved acyl-transferase ribozymes. Earlier studies performed on the in vitro selected acyl-transferase ribozyme, E18 [Suga, H., Cowan, J. A., and Szostak, J. W. (1998) Biochemistry 28, 10118-10125], revealed the requirement of a fully hydrated (outer-sphere) Mg2+ ion for catalytic activity. Interestingly, one class of acyl-transferase ribozymes isolated from the same RNA pool as E18 displays a unique metal dependency and is believed to be interacting with inner-sphere coordinated Mg2+ ions. New results show that one of these inner-sphere coordinating ribozymes, HS01, assumes a cloverleaf secondary structure closely resembling E18, yet apparently facilitates a distinct catalytic mechanism. Furthermore, the nature of the RNA-metal interaction(s) in HS01 seems to be dictating a unique reaction mechanism that exhibits a titratable moiety at a near-neutral pK(a). In light of the critical role metal ions play in biochemistry and the proper function of RNAs, these results compare two distinct manners by which metals serve to promote the catalysis of the same reaction.     

RNA catalysis: ribozymes, ribosomes, and riboswitches

The catalytic mechanisms employed by RNA are chemically more diverse than initially suspected. Divalent metal ions, nucleobases, ribosyl hydroxyl groups, and even functional groups on metabolic cofactors all contribute to the various strategies employed by RNA enzymes. This catalytic breadth raises intriguing evolutionary questions about how RNA lost its biological role in some cases, but not in others, and what catalytic roles RNA might still be playing in biology.     

Role of an active site guanine in hairpin ribozyme catalysis probed by exogenous nucleobase rescue

The hairpin ribozyme is a small catalytic RNA with reversible phosphodiester cleavage activity. Biochemical and structural studies exclude a requirement for divalent metal cation cofactors and implicate one active site nucleobase in particular, G8, in the catalytic mechanism. Our previous work demonstrated that the cleavage activity that is lost when G8 is replaced by an abasic residue is restored when certain nucleobases are provided in solution. The specificity and pH dependence of exogenous nucleobase rescue were consistent with several models of the rescue mechanism, including general acid base catalysis, electrostatic stabilization of negative charge in the transition state or a requirement for protonation to facilitate exogenous nucleobase binding. Detailed analyses of exogenous nucleobase rescue for both cleavage and ligation reactions now allow us to refine models of the rescue mechanism. Activity increased with increasing pH for both unmodified ribozyme reactions and unrescued reactions of abasic variants lacking G8. This similarity in pH dependence argues against a role for G8 as a general base catalyst, because G8 deprotonation could not be responsible for the pH-dependent transition in the abasic variant. Exogenous nucleobase rescue of both cleavage and ligation activity increased with decreasing pH, arguing against a role for rescuing nucleobases in general acid catalysis, because a nucleobase that contributes general acid catalysis in the cleavage pathway should provide general base catalysis in ligation. Analysis of the concentration dependence of cytosine rescue at high and low pH demonstrated that protonation promotes catalysis within the nucleobase-bound ribozyme complex but does not stabilize nucleobase binding in the ground state. These results support an electrostatic stabilization mechanism in which exogenous nucleobase binding counters negative charge that develops in the transition state.     

Nucleobase catalysis in ribozyme mechanism

RNA performs a wide range of functions in biology including catalysis of chemical reactions. A major goal in the field of ribozyme chemical biology is to understand these functions in molecular terms. There is increasing evidence that ribozymes can use their nucleobases directly in chemical catalysis in a variety of ways. These include hydrogen bonding to the transition state, stabilizing charge development, and transferring protons as general acid-base catalysts. This article highlights recent kinetic, structural, single molecule, and synthetic approaches that have been used to probe the roles of ribozyme nucleobases in phosphodiester bond cleavage.     

The variation of catalytic efficiency of Bacillus cereus metallo-beta-lactamase with different active site metal ions

The kinetics and mechanism of hydrolysis of the native zinc and metal substituted Bacillus cereus (BcII) metallo-beta-lactamase have been investigated. The pH and metal ion dependence of k(cat) and k(cat)/K(m), determined under steady-state conditions, for the cobalt substituted BcII catalyzed hydrolysis of cefoxitin, cephaloridine, and cephalexin indicate that an enzyme residue of apparent pK(a) 6.3 +/- 0.1 is required in its deprotonated form for metal ion binding and catalysis. The k(cat)/K(m) for cefoxitin and cephalexin with cadmium substituted BcII is dependent on two ionizing groups on the enzyme: one of pK(a1) = 8.7 +/- 0.1 required in its deprotonated form and the other of pK(a2) = 9.3 +/- 0.1 required in its protonated form for activity. The pH dependence of the competitive inhibition constant, K(i), for CdBcII with l-captopril indicates that pK(a1) = 8.7 +/- 0.1 corresponds to the cadmium-bound water. For the manganese substituted BcII, the pH dependence of k(cat)/K(m) for benzylpenicillin, cephalexin, and cefoxitin similarly indicated the importance of two catalytic groups: one of pK(a1) = 8.5 +/- 0.1 which needs to be deprotonated and the other of pK(a2) = 9.4 +/- 0.1 which needs to be protonated for catalysis; the pK(a1) was assigned to the manganese-bound water. The rate was metal ion concentration dependent at the highest manganese concentrations used (10(-)(3) M). The metal substituted species have similar or higher catalytic activities compared with the zinc enzyme, albeit at pHs above 7. Interestingly, with cefoxitin, a very poor substrate for ZnBcII, both k(cat) and k(cat)/K(m) increase with increasing pK(a) of the metal-bound water, in the order Zn < Co < Mn < Cd. A higher pK(a) for the metal-bound water for cadmium and manganese BCII leads to more reactive enzymes than the native zinc BcII, suggesting that the role of the metal ion is predominantly to provide the nucleophilic hydroxide, rather than to act as a Lewis acid to polarize the carbonyl group and stabilize the oxyanion tetrahedral intermediate.     

A ribonucleopeptide world at the origin of life

The structural flexibility of RNA and its ability to store genetic information has led scientists to postulate that RNA could be the key molecule for the development of life on Earth, further leading to formulate the RNA world hypothesis that received a lot of success and acceptance after the discoveries of the last thirty‐five years. Despite its highly structural and functional significance, the difficulty in synthesizing the four nucleobases that form the RNA polymer from the same primordial soup, its low stability, and limited catalytic repertoire, make the RNA world hypothesis less convincing even though it remains the best explanation for the origin of life. An increasing number of scientists are becoming more supportive of a more realistic approach explaining the appearance of life. In this review, I propose an enhanced explanation for the appearance of life supported by recent discoveries and theories. Accordingly, amino acids and peptides associated with RNA (e.g., ribonucleopeptides) might have existed at the onset of RNA and might have played an important role in the continuous development of self‐sustaining biological systems. Therefore, in this review, I cover the most recent and relevant scientific investigations that propose a better understanding of the ribonucleopeptide world hypothesis and the appearance of life. Finally, I propose two hypotheses for a primitive translation machinery (PTM) that might have been formed of either a T box ribozyme or a ribopolymerase.     

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.     

pH variation of the kinetic parameters and the catalytic mechanism of malic enzyme.

The pH variation of the kinetic parameters for the oxidative decarboxylation of L-malate and decarboxylation of oxalacetate catalyzed by malic enzyme has been used to gain information on the catalytic mechanism of this enzyme. With Mn2+ as the activator, an active-site residue with a pK of 5.4 must be protonated for oxalacetate decarboxylation and ionized for the oxidative decarboxylation of L-malate. With Mg2+ as the metal, this pK is 6, and, at high pH, V/K for L-malate decreases when groups with pKs of 7.8 and 9 are deprotonated. The group at 7.8 is a neutral acid (thought to be water coordinated to Mg2+), while the group at 9 is a cationic acid such as lysine. The V profile for reaction of malate shows these pKs displaced outward by 1.4 pH units, since the rate-limiting step is normally TPNH release, and the chemical reaction, which is pH sensitive, is 25 times faster. TPN binding is decreased by ionization of a group with pK 9.3 or protonation of a group with pK 5.3. The pH variation of the Km for Mg shows that protonation of a group with pK 8.7 (possibly SH) decreases metal binding in the presence of malate by a factor of 1400, and in the absence of malate by a factor of 20. A catalytic mechanism is proposed in which hydride transfer is accompanied by transfer of a proton to the group with pK 5.4-6, and enolpyruvate is protonated by water coordinated to the Mg2+ (pK 7.8) after decarboxylation and release of CO2.     

Detection of large pKa perturbations of an inhibitor and a catalytic group at an enzyme active site, a mechanistic basis for catalytic power of many enzymes

Delta(5)-3-Ketosteroid isomerase catalyzes cleavage and formation of a C-H bond at a diffusion-controlled limit. By determining the crystal structures of the enzyme in complex with each of three different inhibitors and by nuclear magnetic resonance (NMR) spectroscopic investigation, we evidenced the ionization of a hydroxyl group (pK(a) approximately 16.5) of an inhibitor, which forms a low barrier hydrogen bond (LBHB) with a catalytic residue Tyr(14) (pK(a) approximately 11.5), and the protonation of the catalytic residue Asp(38) with pK(a) of approximately 4.5 at pH 6.7 in the interaction with a carboxylate group of an inhibitor. The perturbation of the pK(a) values in both cases arises from the formation of favorable interactions between inhibitors and catalytic residues. The results indicate that the pK(a) difference between catalytic residue and substrate can be significantly reduced in the active site environment as a result of the formation of energetically favorable interactions during the course of enzyme reactions. The reduction in the pK(a) difference should facilitate the abstraction of a proton and thereby eliminate a large fraction of activation energy in general acid/base enzyme reactions. The pK(a) perturbation provides a mechanistic ground for the fast reactivity of many enzymes and for the understanding of how some enzymes are able to extract a proton from a C-H group with a pK(a) value as high as approximately 30.     

Three conserved guanosines approach the reaction site in native and minimal hammerhead ribozymes

Native hammerhead ribozymes contain RNA domains that enable high catalytic activity under physiological conditions, where minimal hammerheads show little activity. However, little is known about potential differences in native versus minimal ribozyme folding. Here, we present results of photocross-linking analysis of native and minimal hammerheads containing photoreactive nucleobases 6-thioguanosine, 2,6-diaminopurine, 4-thiouridine, and pyrrolocytidine, introduced at specific sites within the catalytic core. Under conditions where catalytic activity is observed, the two substrate nucleobases spanning the cleavage site approach and stack upon G8 and G12 of the native hammerhead, two conserved nucleobases that show similar behavior in minimal constructs, have been implicated in general acid-base catalysis, and are >15 A from the cleavage site in the crystal structures. Pyrrolocytidine at cleavage site position 17 forms an efficient crosslink to G12, and the crosslinked RNA retains catalytic activity. Multiple cross-linked species point to a structural rearrangement within the U-turn, positioning residue G5 in the vicinity of cleavage site position 1.1. Intriguing crosslinks were triggered by nucleotide analogues at positions distal to the crosslinked residues; for example, 6-thioguanosine at position 5 induced a crosslink between G12 and C17, suggesting an intimate functional communication among these three nucleobases. Together, these results support a model in which the native hammerhead folds to an active structure similar to that of the minimal ribozyme, and significantly different from the crystallographic structures.     

Investigation of the role of the histidine-aspartate pair in the human exonuclease III-like abasic endonuclease,Ape1

Hydrogen bonded histidine-aspartate (His-Asp) pairs are critical constituents in several key enzymatic reactions. To date, the role that these pairs play in catalysis is best understood in serine and trypsin-like proteases, where structural and biochemical NMR studies have revealed important pK(a) values and hydrogen bonding patterns within the catalytic pocket. However, the role of the His-Asp pair in metal-assisted catalysis is less clear. Here, we apply liquid-state NMR to investigate the role of a critical histidine residue of apurinic endonuclease 1 (Ape1), a human DNA repair enzyme that cleaves adjacent to abasic sites in DNA using one or more divalent cations and an active-site His-Asp pair. The results of these studies suggest that the Ape1 His-Asp pair does not function as either a general base catalyst or a metal ligand. Rather, the pair likely stabilizes the pentavalent transition state necessary for phospho-transfer.     

Defining the catalytic metal ion interactions in the Tetrahymena ribozyme reaction

Divalent metal ions play a crucial role in catalysis by many RNA and protein enzymes that carry out phosphoryl transfer reactions, and defining their interactions with substrates is critical for understanding the mechanism of biological phosphoryl transfer. Although a vast amount of structural work has identified metal ions bound at the active site of many phosphoryl transfer enzymes, the number of functional metal ions and the full complement of their catalytic interactions remain to be defined for any RNA or protein enzyme. Previously, thiophilic metal ion rescue and quantitative functional analyses identified the interactions of three active site metal ions with the 3'- and 2'-substrate atoms of the Tetrahymena group I ribozyme. We have now extended these approaches to probe the metal ion interactions with the nonbridging pro-S(P) oxygen of the reactive phosphoryl group. The results of this study combined with previous mechanistic work provide evidence for a novel assembly of catalytic interactions involving three active site metal ions. One metal ion coordinates the 3'-departing oxygen of the oligonucleotide substrate and the pro-S(P) oxygen of the reactive phosphoryl group; another metal ion coordinates the attacking 3'-oxygen of the guanosine nucleophile; a third metal ion bridges the 2'-hydroxyl of guanosine and the pro-S(P) oxygen of the reactive phosphoryl group. These results for the first time define a complete set of catalytic metal ion/substrate interactions for an RNA or protein enzyme catalyzing phosphoryl transfer.     

pH studies on the chemical mechanism of rabbit muscle pyruvate kinase. 2. Physiological substrates and phosphoenol-alpha-ketobutyrate

pH profiles have been determined for the reactions catalyzed by pyruvate kinase between pyruvate and MgATP and between phosphoenolpyruvate and MgADP. V, V/KMgATP, and V/Kpyruvate all decrease below a pK of 8.3 and above one of 9.2. The group with pK = 8.3 is probably a lysine that removes the proton from pyruvate during enolization, while the pK of 9.2 is that of water coordinated to enzyme-bound Mg2+. The fact that this pK shows in all three pH profiles shows that pyruvate forms a predominantly second sphere complex and cannot replace hydroxide to form the inner sphere complex that results in enolization and subsequent phosphorylation. On the basis of the displacement of the pK of the acid-base catalytic group in its V/K profile, phosphoenolpyruvate is a sticky substrate, reacting to give pyruvate approximately 5 times faster than it dissociates. The V/K profile for the slow substrate phosphoenol-alpha-ketobutyrate shows the pK of 8.3 for the acid-base catalytic group in its correct position, but this group must be protonated so that it can donate a proton to the intermediate enolate following phosphoryl transfer. The secondary phosphate pK of the substrate is seen in this V/K profile as well as in the pKi profile for phosphoglycolate (but not in those for glycolate O-sulfate or oxalate), showing a preference for the trianion for binding. The chemical mechanism with the natural substrates thus appears to involve phosphoryl transfer between MgADP and a Mg2+-bound enolate with metal coordination of the enolate serving to make it a good leaving group.