Studies of nucleic acid-like polymers as catalysts

Summary An important issue in the problem of the origins of life is whether or not nucleic acids may exert catalytic activities. In order to study the possible role of the adenine ring in catalysis, we have synthesized polymers containing aliphatic amino groups and the nucleic base adenine linked to macromolecules by its 6-amino group. These polymers exhibit pronounced catalytic activities in the hydrolysis of p-nitrophenylacetate. In mild basic conditions, the strong increase in the activities observed can be related to a cooperative effect between the amino groups and the adenine rings of the polymers. These properties and our previous results on the catalytic activity of N6-ribosyl-adenine are consistent with a possible role for the adenine ring in prebiotic catalysis. Ofprint requests to: M.C. Maurel     

Catalysis by a prebiotic nucleotide analog of histidine

A ribosylated derivative of adenine, N6 ribosyl adenine, likely to have formed under prebiotic synthesis conditions, is shown to be as active as histidine in the model reaction of p-nitrophenyl acetate hydrolysis. This property widens the range of reactions accessible to RNA catalysis.     

Adenine protonation in domain B of the hairpin ribozyme

Protein enzymes often use ionizable side chains, such as histidine, for general acid-base catalysis because the imidazole pK(a) is near neutral pH. RNA enzymes, on the other hand, are comprised of nucleotides which do not have apparent pK(a) values near neutral pH. Nevertheless, it has been recently shown that cytidine and adenine protonation can play an important role in both nucleic acid structure and catalysis. We have employed heteronuclear NMR methods to determine the pK(a) values and time scales of chemical exchanges associated with adenine protonation within the catalytically essential B domain of the hairpin ribozyme. The large, adenine-rich internal loop of the B domain allows us to determine adenine pK(a) values for a variety of non-Watson-Crick base pairs. We find that adenines within the internal loop have pK(a) values ranging from 4.8 to 5.8, significantly higher than the free mononucleotide pK(a) of 3. 5. Adenine protonation results in potential charge stabilization, hydrogen bond formation, and stacking interactions that are expected to stabilize the internal loop structure at low pH. Fast proton exchange times of 10-50 micros were determined for the well-resolved adenines. These results suggest that shifted pK(a) values may be a common feature of adenines in non-Watson-Crick base pairs, and identify two adenines which may participate in hairpin ribozyme active site chemistry.     

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.     

The prebiotic synthesis and catalytic role of imidazoles and other condensing agents

In the past decade significant advances have been made in the synthesis of oligonucleotides and other polymers by means of imidazoles and other condensing agents. In spite of the current knowledge of the chemistry of imidazoles and their importance as prebiotic catalysts, their formation under primitive earth conditions has not been properly demonstrated. We have now been able to synthesize imidazole as well as its 2-methyl and 4-methyl derivatives under plausible prebiotic conditions. One method utilizes an aldehyde (formaldehyde or acetaldehyde), glyoxal and ammonia as the starting materials for the formation of imidazole and 2-methylimidazole. The other method uses a carbohydrate and ammonia as the key reagents for the synthesis of 4-methylimidazole. The importance of imidazole and related compounds (e.g., cyanamide) in the synthesis of oligonucleotides has been studied by us as well as others. Apparently the charge relay group (-N-C-N-) present in imidazoles, carbodiimides, cyanamide, or the histidine and arginine of enzyme active centers is essential for the synthesis of phosphodiester and pyrophosphate bonds.     

The prebiotic synthesis and catalytic role of imidazoles and other condensing agents

In the past decade significant advances have been made in the synthesis of oligonucleotides and other polymers by means of imidazoles and other condensing agents. In spite of the current knowledge of the chemistry of imidazoles and their importance as prebiotic catalysts, their formation under primitive earth conditions has not been properly demonstrated. We have now been able to synthesize imidazole as well as its 2-methyl and 4-methyl derivatives under plausible prebiotic conditions. One method utilizes an aldehyde (formaldehyde or acetaldehyde), glyoxal and ammonia as the starting materials for the formation of imidazole and 2-methylimidazole. The other method uses a carbohydrate and ammonia as the key reagents for the synthesis of 4-methylimidazole. The importance of imidazole and related compounds (e.g., cyanamide) in the synthesis of oligonucleotides has been studied by us as well as others. Apparently the charge relay group (–N–C–N–) present in imidazoles, carbodiimides, cyanamide, or the histidine and arginine of enzyme active centers is essential for the synthesis of phosphodiester and pyrophosphate bonds.     

The role of an active site histidine in the catalytic mechanism of aspartate transcarbamoylase

Although the allosteric enzyme aspartate transcarbamoylase from Escherichia coli has been the focus of numerous physical and enzymological studies for over 2 decades, the catalytic mechanism is still poorly understood. There has been much speculation regarding the role of a conserved histidine residue at position 134 which recent crystallographic studies have implicated in the catalytic mechanism as a general acid or as a general base. We have used a combination of site-directed mutagenesis, 13C-isotope incorporation, and high field NMR to probe the role of His134 in the catalytic mechanism of aspartate transcarbamoylase. By comparing the wild-type catalytic trimer with that from a partially active mutant in which His134 is replaced by alanine, we have assigned the 13C resonance for His134 in the wild-type enzyme. This residue is shown to have a pK less than 6, indicating that the imidazole ring is unprotonated at pH values optimal for enzymatic activity (pH 8.0). This result eliminates the possibility of His134 participating as a general acid in the carbamoyl transfer mechanism. Since the crystallographic studies indicate that His134 is close enough to hydrogen-bond to the carbonyl of the liganded bisubstrate analog N-(phosphonacetyl)-L-aspartate, the imidazole ring would be oriented as to make it unlikely that the N1 lone pair of electrons could participate in general base catalysis. Moreover, if His134 is implicated in base catalysis, we would have expected a much greater loss of activity upon its replacement by alanine. Perhaps the role of His134 is merely to help position the carbonyl group of carbamoyl phosphate for nucleophilic attack by the alpha-amino group of aspartate.     

General acid catalysis by the hepatitis delta virus ribozyme

Recent crystallographic and functional analyses of RNA enzymes have raised the possibility that the purine and pyrimidine nucleobases may function as general acid-base catalysts. However, this mode of nucleobase-mediated catalysis has been difficult to establish unambiguously. Here, we used a hyperactivated RNA substrate bearing a 5'-phosphorothiolate to investigate the role of a critical cytosine residue in the hepatitis delta virus ribozyme. The hyperactivated substrate specifically suppressed the deleterious effects of cytosine mutations and pH changes, thereby linking the protonation of the nucleobase to leaving-group stabilization. We conclude that the active-site cytosine provides general acid catalysis, mediating proton transfer to the leaving group through a protonated N3-imino nitrogen. These results establish a specific role for a nucleobase in a ribozyme reaction and support the proposal that RNA nucleobases may function in a manner analogous to that of catalytic histidine residues in protein enzymes.     

Small cofactors may assist protein emergence from RNA world: clues from RNA-protein complexes

It is now widely accepted that at an early stage in the evolution of life an RNA world arose, in which RNAs both served as the genetic material and catalyzed diverse biochemical reactions. Then, proteins have gradually replaced RNAs because of their superior catalytic properties in catalysis over time. Therefore, it is important to investigate how primitive functional proteins emerged from RNA world, which can shed light on the evolutionary pathway of life from RNA world to the modern world. In this work, we proposed that the emergence of most primitive functional proteins are assisted by the early primitive nucleotide cofactors, while only a minority are induced directly by RNAs based on the analysis of RNA-protein complexes. Furthermore, the present findings have significant implication for exploring the composition of primitive RNA, i.e., adenine base as principal building blocks.     

Multiple Forms of Rice Seeds β-Amylases on Zymogram

Hen lysozyme modified with histamine (HML) and Japanese quail lysozyme (JQL) were treated with immobilized metal ion affinity chromatography to analyze the states of their imidazole groups. When Ni(II) was used as the metal ion immobilized, JQL was strongly retained in a Ni(II)-chelating Sepharose column, while hen lysozyme and HML were hardly retained in the same column. All of these lysozymes have a histidine imidazole group at the 15th position, while JQL has an additional histidine imidazole group at the 103rd position and HML has an additional imidazole group covalently attached to Asp101. Thus, I concluded that the imidazole group at the 103rd position of JQL is exposed to the solvent and recognized by the metal ion, but that the imidazole group attached to Asp101 in HML is localized to a hydrophobic region and not recognized by the metal ion.     

Insight into G-quadruplex-hemin DNAzyme/RNAzyme: adjacent adenine as the intramolecular species for remarkable enhancement of enzymatic activity

G-quadruplex (G4) with stacked G-tetrads structure is able to bind hemin (iron (III)-protoporphyrin IX) to form a unique type of DNAzyme/RNAzyme with peroxidase-mimicking activity, which has been widely employed in multidisciplinary fields. However, its further applications are hampered by its relatively weak activity compared with protein enzymes. Herein, we report a unique intramolecular enhancement effect of the adjacent adenine (EnEAA) at 3′ end of G4 core sequences that significantly improves the activity of G4 DNAzymes. Through detailed investigations of the EnEAA, the added 3′ adenine was proved to accelerate the compound I formation in catalytic cycle and thus improve the G4 DNAzyme activity. EnEAA was found to be highly dependent on the unprotonated state of the N1 of adenine, substantiating that adenine might function as a general acid–base catalyst. Further adenine analogs analysis supported that both N1 and exocyclic 6-amino groups in adenine played key role in the catalysis. Moreover, we proved that EnEAA was generally applicable for various parallel G-quadruplex structures and even G4 RNAzyme. Our studies implied that adenine might act analogously as the distal histidine in protein peroxidases, which shed light on the fundamental understanding and rational design of G4 DNAzyme/RNAzyme catalysts with enhanced functions.     

Phosphorylation of glucose mediated by imidazole-containing catalysts

Histidine and some histidine derivatives were found to catalyze the synthesis of glucose phosphate from glucose and inorganic phosphate. A free imidazole ring with the N-1 proton possibly hydrogen bonded to a proximal carboxylate anion was required for catalysis in this system. A free amine group located near the imidazole was also required. Intermediates probably include (1) an imine formed between the amine of histidine and the carbohydrate carbonyl group and (2) phosphohistidine, in which phosphate is attached to N-1 of histidine.     

Chemical properties of the histidine residue of secretin: evidence for a specific intramolecular interaction

Secretin has a single histidine residue located at the amino terminus which plays a crucial role in its biological activity. The chemical properties, viz. pK and reactivity, of the alpha-amino and imidazole groups of this residue were determined at a secretin concentration of 10(-6) M in 0.1 M KCl at 37 degrees C. Competitive labelling using tritiated 1-fluoro-2,4-dinitrobenzene (DNP-F) as the labelling reagent was the experimental approach employed. The alpha-amino group was found to have a pK value of 8.83 and a reactivity 5-times that of the alpha-amino group in the model compound, histidylglycine. For the imidazole function a pK value of 8.24 and a reactivity 26-times that of the imidazole function in histidylglycine was found. Both these groups in secretin had pK values which were shifted one pK unit higher than in histidylglycine, but like the model compound the reactivity of the imidazole function was still linked to the state of ionization of the alpha-amino group. These observations are interpreted as evidence for the existence of a major conformational state in dilute aqueous solution in which the amino-terminal histidine of secretion is interacting with a negatively charged carboxyl group.     

Factors determining the orientation of axially coordinated imidazoles in heme proteins.

Factors determining conformations of imidazole axially coordinated to heme in heme proteins were investigated by analyzing 693 hemes in 432 different crystal structures of heme proteins from the Protein Data Bank (PDB), where at least one histidine is ligated to heme. The results from a search of the PDB for protein structures were interpreted with molecular force field computations. Analysis of data from these crystal structures indicated that there are two main factors that determine the orientations of imidazole ligated to heme. These are the interactions of imidazole with the propionic acid side chains of heme and with the histidine backbone. From the analysis of the crystal structures of heme proteins, it turned out that the hydrogen bonding pattern is often not decisive, though it is probably used by nature to fine-tune the orientation of imidazole axially ligated to heme. We found that in many heme proteins the NdeltaH group of imidazole ligated to heme can assume a number of different hydrogen bonds and that in mutant structures the orientation of the ligated imidazole often does not change significantly, although the mutant altered the hydrogen bonding scheme involving the imidazole. Data from crystal structures of heme proteins show that there are preferred orientations of imidazoles with respect to heme. Generally, the NdeltaH group of imidazole is oriented toward the propionic acid groups of the heme. In some cases, the NdeltaH group of imidazole is close to only one of the propionic acid groups, but it is practically never oriented in the opposite direction. The imidazole also adopts a preferred orientation with respect to its histidine backbone such that the plane of the imidazole ring is practically never parallel to the Calpha-Cbeta bond of its histidine backbone. For a given conformation of histidine backbone with respect to heme, as well as imidazole with respect to histidine backbone, the orientation of the imidazole with respect to heme is uniquely determined, since the three orientations depend on each other. Hence, the interaction of the imidazole with the backbone also influences the orientation of the imidazole with respect to the heme. Force field computations are in agreement with experimental data. With this method, we showed that there is an energy minimum when the NdeltaH group of the imidazole is oriented toward the propionic acid groups and that there are minima of energy for orientations where the imidazole ring is orthogonal to the plane defined by the Calpha-Cbeta and Cbeta-Cgamma bonds of the histidine. The computations also demonstrated that these interactions are mainly of electrostatic origin. By taking into account these two major factors, we were able to understand the orientations of axially coordinated imidazoles for all groups of heme proteins, except for the group of cytochrome c peroxidase. In this group, the orientation of the imidazole is determined by a strong hydrogen bond of the NdeltaH group with Asp235.     

Errors and alternatives in prebiotic replication and catalysis

The work on nonenzymatic nucleic acid replication performed by Leslie Orgel and co-workers over the last four decades, now extended by work on artificial selection of RNA aptamers and ribozymes, is generating some pessimism concerning the 'naked gene' theories of the origin of life. It is suggested here that the low probability of finding RNA aptamers and ribozymes within pools of random sequences is not as disquieting as the poor gain in efficiency obtained with increases in information content. As acknowledged by Orgel and many other authors, primitive RNA replication and catalysis must have occurred within already complex and dynamic environments. I, thus, propose to pay attention to a number of possibilities that bridge the gap between 'naked gene' theories, on one side, and metabolic theories in which complex systems self-propagate by growth and fragmentation, on the other side. For instance, one can de-emphasize nucleotide-by-nucleotide replication leading to long informational polymers, and view instead long random polymers as storage devices, from which shorter oligomers are excised. Catalytic tasks would be mainly performed by complexes associating two or more oligomers belonging to the same or to different chemical families. It is proposed that the problems of stability, binding affinity, reactivity, and specificity could be easier to handle by heterogeneous complexes of short oligomers than by long, single-stranded polymers. Finally, I point out that replication errors in a primitive replication context should include incorporations of alternative nucleotides with interesting, chemically reactive groups. In this way, an RNA sequence could be at the same time an inert sequence when copied without error, and a ribozyme, when a chemically reactive nucleotide is inadvertently introduced during replication.     

Metal binding modes of Alzheimer's amyloid beta-peptide in insoluble aggregates and soluble complexes

Aggregation of the amyloid beta-peptide (Abeta) into insoluble fibrils is a key pathological event in Alzheimer's disease. Zn(II) induces the Abeta aggregation at acidic-to-neutral pH, while Cu(II) is an effective inducer only at mildly acidic pH. We have examined Zn(II) and Cu(II) binding modes of Abeta and their pH dependence by Raman spectroscopy. The Raman spectra clearly demonstrate that three histidine residues in the N-terminal hydrophilic region provide primary metal binding sites and the solubility of the metal-Abeta complex is correlated with the metal binding mode. Zn(II) binds to the N(tau) atom of the histidine imidazole ring and the peptide aggregates through intermolecular His(N(tau))-Zn(II)-His(N(tau)) bridges. The N(tau)-metal ligation also occurs in Cu(II)-induced Abeta aggregation at mildly acidic pH. At neutral pH, however, Cu(II) binds to N(pi), the other nitrogen of the histidine imidazole ring, and to deprotonated amide nitrogens of the peptide main chain. The chelation of Cu(II) by histidine and main-chain amide groups results in soluble Cu(II)-Abeta complexes. Under normal physiological conditions, Cu(II) is expected to protect Abeta against Zn(II)-induced aggregation by competing with Zn(II) for histidine residues of Abeta.     

Catalysis by Glomerella cingulata cutinase requires conformational cycling between the active and inactive states of its catalytic triad

Cutinase belongs to a group of enzymes that catalyze the hydrolysis of esters and triglycerides. Structural studies on the enzyme from Fusarium solani have revealed the presence of a classic catalytic triad that has been implicated in the enzyme's mechanism. We have solved the crystal structure of Glomerella cingulata cutinase in the absence and in the presence of the inhibitors E600 (diethyl p-nitrophenyl phosphate) and PETFP (3-phenethylthio-1,1,1-trifluoropropan-2-one) to resolutions between 2.6 and 1.9 Å. Analysis of these structures reveals that the catalytic triad (Ser136, Asp191, and His204) adopts an unusual configuration with the putative essential histidine His204 swung out of the active site into a position where it is unable to participate in catalysis, with the imidazole ring 11 Å away from its expected position. Solution-state NMR experiments are consistent with the disrupted configuration of the triad observed crystallographically. H204N, a site-directed mutant, was shown to be catalytically inactive, confirming the importance of this residue in the enzyme mechanism. These findings suggest that, during its catalytic cycle, cutinase undergoes a significant conformational rearrangement converting the loop bearing the histidine from an inactive conformation, in which the histidine of the triad is solvent exposed, to an active conformation, in which the triad assumes a classic configuration.     

The role of electrostatic interactions in the mechanism of peptide bond hydrolysis by a Ser-Lys catalytic dyad.

General-base catalysis in the active site of serine proteases is carried out by the imidazole side chain of a histidine. During formation of the transition state, an adjacent carboxylic acid group stabilizes the positive charge that forms on the general-base catalyst and as a result contributes several orders of magnitude to the catalytic efficiency of these enzymes. In the recently discovered family of self-cleaving proteins exemplified by the LexA repressor of Escherichia coli, instead of the imidazole of a histidine, the active-site general-base catalyst was found to be the epsilon-amino of a lysine. The considerably higher capacity of the lysine side chain for proton acceptance raises interesting questions concerning the role of electrostatic interactions in the mechanism of proton transfer by this highly basic group. The negative charge elimination studies described here and their effects on the kmax and pK of LexA self-cleavage are consistent with a model in which electrostatic interactions between an acidic side chain and the general-base catalyst form a barrier to proton transfer. The implications are that the epsilon-amino group, unlike the imidazole group, is capable of effecting proton transfer without the intervention of a countercharge.     

ATP-analogues as substrates for the leucyl-tRNA synthetase from Escherichia coli MRE 600.

No analogous nucleoside triphosphate was found which acts as well as ATP in binding to and supporting catalysis of leucyl-tRNA synthetase from Escherichia coli MRE 600. However, there are numerous nucleotides which are able to replace ATP, but with lower efficiency. The 6-amino group of the adenine ring and the 2'-hydroxyl group of the ribose ring are essential for binding and catalytic activity. Alterations in the triphosphate moiety of the molecule can cause drastic changes in Km and/or Vmax, whereas alterations of the imidazole ring and substitutions at the 8-position of the adenine ring cause only minor losses of catalytic activity.     

Synthesis of new polymer-bound adenine nucleotides using starburst PAMAM dendrimers

Two types of new polymer-bound adenine nucleotides were synthesized by coupling adenine nucleotides (ATP and ADP) with starburst polyamidoamine (PAMAM) dendrimers. The first type was obtained by coupling native adenine nucleotides directly with a carboxy-terminated PAMAM dendrimer. In the second type, the nucleotides were modified by introducing a spacer arm containing a carboxylic end group (N(6)-R-ATP and N(6)-R-ADP) and coupled with an amine-terminated PAMAM dendrimer. Both types of the dendrimers were coupled with native or the modified nucleotides using the well-known carbodiimide activation technique. The optimum coupling pH and temperature were 4 and 30 degrees C, respectively, for preparing the carboxy-terminated PAMAM-bound ATP or ADP, and were 9 and 50 degrees C, respectively, for preparing the amine-terminated PAMAM-bound N(6)-R-ATP or N(6)-R-ADP. The ATP or ADP contents in the synthesized polymers were found to be 4 mol of ATP or of ADP/mol of carboxy-terminated PAMAM-bound ATP or ADP and 25 mol of ATP or of ADP/mol of amine-terminated PAMAM-bound N(6)-R-ATP or N(6)-R-ADP. The coenzymatic activities relative to the native ATP of the carboxy-terminated PAMAM-bound ATP against glucokinase and hexokinase were 16 and 7%, respectively, and those of the amine-terminated PAMAM-bound N(6)-R-ATP 2 and 1%, respectively. The coenzymatic activities relative to the native ADP of the carboxy-terminated PAMAM-bound ADP and the amine-terminated PAMAM-bound N(6)-R-ADP against acetate kinase were 24 and 3.5%, respectively.