Hydrolytic stability of 2′,3′-O-methyleneadenos-5′-yl 2′,5′-di-O-methylurid-3′-yl 5′-O-methylurid-3′(2′)-yl phosphate: implications to feasibility of existence of phosphate-branched RNA under physiological conditions

Phosphodiester models for cleavage of nucleic acids

Nucleic acids that store and transfer biological information are polymeric diesters of phosphoric acid. Cleavage of the phosphodiester linkages by protein enzymes, nucleases, is one of the underlying biological processes. The remarkable catalytic efficiency of nucleases, together with the ability of ribonucleic acids to serve sometimes as nucleases, has made the cleavage of phosphodiesters a subject of intensive mechanistic studies. In addition to studies of nucleases by pH-rate dependency, X-ray crystallography, amino acid/nucleotide substitution and computational approaches, experimental and theoretical studies with small molecular model compounds still play a role. With small molecules, the importance of various elementary processes, such as proton transfer and metal ion binding, for stabilization of transition states may be elucidated and systematic variation of the basicity of the entering or departing nucleophile enables determination of the position of the transition state on the reaction coordinate. Such data is important on analyzing enzyme mechanisms based on synergistic participation of several catalytic entities. Many nucleases are metalloenzymes and small molecular models offer an excellent tool to construct models for their catalytic centers. The present review tends to be an up to date summary of what has been achieved by mechanistic studies with small molecular phosphodiesters.

Can phosphate-branched RNA persist under physiological conditions?

A 2'-O-methyl-RNA oligonucleotide containing a single free 2'-OH group flanking a branching phosphotriester linkage was prepared as a model for phosphate-branched RNA by using an orthogonally protected dimeric phosphoramidite building block in solid-phase synthesis. The strategy allows the synthesis of phosphate-branched oligonucleotides, the three branches of which may be of any desired sequence. Hydrolytic reactions of the phosphotriester linkages in such oligonucleotides were studied at physiological pH in the presence (and absence) of various complementary oligonucleotides. The fully hybridized oligonucleotide model is an order of magnitude more stable than its single-stranded counterpart, which, in turn, is an order of magnitude more stable than its trinucleoside phosphotriester core lacking any oligonucleotide arms. Furthermore, kinked structures obtained by hybridizing the phosphate-branched oligonucleotide with partially complementary oligonucleotides are three to five times more stable than fully double-stranded ones and only approximately three times less stable than the so-called RNA X structure, which has been postulated to incorporate an RNA phosphotriester linkage. The results indicate that when the intrinsically unstable RNA phosphotriester linkage is embedded in an oligonucleotide of appropriate tertiary structure, its half-life can be at least several hours.

Synthesis and enzymatic deprotection of biodegradably protected dinucleoside-2',5'-monophosphates: 3-(acetyloxy)-2,2-bis(ethoxycarbonyl)propyl phosphoesters of 3'-O-(acyloxymethyl)adenylyl-2',5'-adenosines

As a first step towards a viable prodrug strategy for short oligoribonucleotides, such as 2-5A and its congeners, adenylyl-2',5'-adenosines bearing a 3-(acetyloxy)-2,2-bis(ethoxycarbonyl)propyl group at the phosphate moiety, and an (acetyloxy)methyl- or a (pivaloyloxy)methyl-protected 3'-OH group of the 2'-linked nucleoside have been prepared. The enzyme-triggered removal of these protecting groups by hog liver carboxyesterase at pH 7.5 and 37° has been studied. The (acetyloxy)methyl group turned out to be too labile for the 3'-O-protection, being removed faster than the phosphate-protecting group, which results in 2',5'- to 3',5'-isomerization of the internucleosidic phosphoester linkage. In addition, the starting material was unexpectedly converted to the 5'-O-acetylated derivative. (Pivaloyloxy)methyl group appears more appropriate for the purpose. The fully deprotected 2',5'-ApA was accumulated as a main product, although, even in this case, the isomerization of the starting material takes place.

Phosphorane intermediate vs. leaving group stabilization by intramolecular hydrogen bonding in the cleavage of trinucleoside monophosphates: implications for understanding catalysis by the large ribozymes

Hydrolysis of 2',3'-O-methyleneadenosin-5'-yl 5'-O-methyluridin-2'-yl 5'-O-methyl-2'-trifluoroacetamido-2'-deoxyuridin-3'-yl phosphate (1b) has been followed by HPLC over a wide pH range to study the effects of potential hydrogen bonding interactions of the 2'-trifluoroacetamido function on the rate and product distribution of the reaction. At pH < 2, decomposition of 1b (and its 3',3',5'-isomer 1a) is first-order in hydronium-ion concentration and cleavage of the P-O3' bond of the 2'-trifluoroacetamido-modified nucleoside is slightly favored over cleavage of the P-O5' bond. Between pH 2 and 4, the overall hydrolysis is pH-independent and the P-O3' and P-O5' bonds are cleaved at comparable rates. At pH 5, the reaction becomes first-order in hydroxide-ion concentration, with P-O3' bond cleavage predominating. At 10 mmol L(-1) aqueous sodium hydroxide, no P-O5' bond cleavage is observed. Compared to the 2'-OH counterpart , a modest rate enhancement is observed over the entire pH range studied. The absence of P-O5' fission under alkaline conditions suggests hydrogen bond stabilization of the departing 3'-oxyanion by the neighboring 2'-trifluoroacetamido function.

Hydrolytic stability of a phosphate-branched oligonucleotide incorporating a ribonucleoside 3'-phosphotriester unit

A phosphate-branched oligonucleotide has been prepared by using an appropriately protected trinucleoside phosphotriester building block in conventional solid-phase synthesis. Hydrolysis of the branched oligonucleotide has been followed over a wide pH range. Comparison of the present results with those previously obtained for simpler analogues indicates that a trinucleoside 3',3',5'-monophosphate, when embedded in an oligonucleotide structure, is stabilized toward hydroxide-ion catalyzed cleavage by more than one order of magnitude, lending some support to the feasibility of existence of phosphate-branched RNA X in biological systems.

Thio effects on the departure of the 3'-linked ribonucleoside from diribonucleoside 3',3'-phosphorodithioate diesters and triribonucleoside 3',3',5'-phosphoromonothioate triesters: implications for ribozyme catalysis

To provide a solid chemical basis for the mechanistic interpretations of the thio effects observed for large ribozymes, the cleavage of triribonucleoside 3',3',5'-phosphoromonothioate triesters and diribonucleoside 3',3'-phosphorodithioate diesters has been studied. To elucidate the role of the neighboring hydroxy group of the departing 3'-linked nucleoside, hydrolysis of 2',3'-O-methyleneadenosin-5'-yl bis[5'-O-methyluridin-3'-yl] phosphoromonothioate (1 a) has been compared to the hydrolysis of 2',3'-O-methyleneadenosin-5'-yl 5'-O-methyluridin-3'-yl 2',5'-di-O-methyluridin-3'-yl phosphoromonothioate (1 b) and the hydrolysis of bis[uridin-3'-yl] phosphorodithioate (2 a) to the hydrolysis of uridin-3'-yl 2',5'-di-O-methyluridin-3'-yl phosphorodithioate (2 b). The reactions have been followed by RP HPLC over a wide pH range. The phosphoromonothioate triesters 1 a,b undergo two competing reactions: the starting material is cleaved to a mixture of 3',3'- and 3',5'-diesters, and isomerized to 2',3',5'- and 2',2',5'-triesters. With phosphorodithioate diesters 2 a,b, hydroxide-ion-catalyzed cleavage of the P--O3' bond is the only reaction detected at pH >6, but under more acidic conditions desulfurization starts to compete with the cleavage. The 3',3'-diesters do not undergo isomerization. The hydroxide-ion-catalyzed cleavage reaction with both 1 a and 2 a is 27 times as fast as that compared with their 2'-O-methylated counterparts 1 b and 2 b. The hydroxide-ion-catalyzed isomerization of the 3',3',5'-triester to 2',3',5'- and 2',2',5'-triesters with 1 a is 11 times as fast as that compared with 1 b. These accelerations have been accounted for by stabilization of the anionic phosphorane intermediate by hydrogen bonding with the 2'-hydroxy function. Thio substitution of the nonbridging oxygens has an almost negligible influence on the cleavage of 3',3'-diesters 2 a,b, but the hydrolysis of phosphoromonothioate triesters 1 a,b exhibits a sizable thio effect, k(PO)/k(PS)=19. The effects of metal ions on the rate of the cleavage of diesters and triesters have been studied and discussed in terms of the suggested hydrogen-bond stabilization of the thiophosphorane intermediates derived from 1 a and 2 a.

Chemical models for ribozyme action

Mechanistic studies of the action of catalytic ribonucleic acids, ribozymes, are highly challenging, because even a slight structural change can dramatically affect the chain folding. This, in turn, alters the binding properties of the catalytic core, making identification of the real origin of the observed influence on rate difficult. Unambiguous structure-reactivity correlations based on studies with structurally simplified chemical models may help to distinguish between alternative mechanistic interpretations. The results of such model studies are reviewed. The topics include intramolecular cleavage of RNA phosphodiester bonds by solvent-derived species, general acids/bases and metal ions, effect of molecular environment on their hydrolytic stability and trinucleoside monophosphates as models for large ribozymes.

Hydrolysis of 2',3'-O-methyleneadenosin-5'-yl bis-5'-O-methyluridin-3'-yl phosphate: the 2'-hydroxy group stabilizes the phosphorane intermediate, not the departing 3'-oxyanion, by hydrogen bonding

Hydrolytic reactions of 2',3'-O-methyleneadenosin-5'-yl bis-5'-O-methyluridin-3'-yl phosphate (1a) have been followed by RP HPLC over a wide pH range to elucidate the role of the 2'-OH group as an intermolecular hydrogen bond donor facilitating the cleavage of 1a. At pH < 2, where the decomposition of 1 is first-order in hydronium-ion concentration, the P-O5' and P-O3' bonds are cleaved equally rapidly. Over a relatively wide range from pH 2 to 4, the hydrolysis is pH-independent and the P-O5' bond is cleaved 1.6 times as rapidly as the P-O3' bond. At pH 6, the reaction becomes first-order in hydroxide-ion concentration and cleavage of the P-O3' bond starts to predominate, accounting for 89% of the overall hydrolysis in 10 mmol L(-)(1) aqueous sodium hydroxide. Under alkaline conditions, the 2'-OH group facilitates the cleavage of 1 by a factor of 27 compared to the 2'-OMe counterpart, the influence on the P-O3' and P-O5' bond cleavage being equal. Accordingly, the 2'-hydroxy group stabilizes the phosphorane intermediate, not the departing 3'-oxyanion, by hydrogen bonding.