2′,3′-O-Phosphonoalkylidene derivatives of ribonucleosides: Synthesis and reactivity

Tuning the hybridization properties of modified oligonucleotides: from flexible to conformationally constrained phosphonate internucleotide linkages

The concept of conformational restriction leading to the preorganization of modified strands has proven to be successful and has afforded nucleic acid analogues with many interesting properties suitable for various biochemical applications. We utilized this concept to prepare a set of constrained oligonucleotides derived from 1,4-dioxane and 1,3-dioxolane-locked nucleoside phosphonates and evaluated their hybridization affinities towards their complementary RNA strands. With an increase of ΔT_m per modification up to +5.2 °C, the hybridization experiments revealed the (S)-2',3'-O-phosphonomethylidene internucleotide linkage as one of the most T_m-increasing modifications reported to date. Moreover, we introduced a novel prediction tool for the pre-selection of potentially interesting chemical modifications of oligonucleotides.

Synthesis of Morpholino Monomers, Chlorophosphoramidate Monomers, and Solid-Phase Synthesis of Short Morpholino Oligomers

Phosphorodiamidate morpholino oligomers (PMOs) are a highly capable class of synthetic antisense oligonucleotides that are used to study gene functions in in vitro and in vivo models. This unit describes the synthesis of exocyclic-amine-protected 7'-hydroxy and 7'-chlorophosphoramidate-activated morpholino monomers of A, T, G, and C, together with their incorporation into short PMO oligomers by solid-phase synthesis. Starting from ribonucleosides, the exocyclic-amine-protected 7'-hydroxy monomers are prepared following a modified Summerton protocol, which consists of a periodate cleavage/Schiff base formation/reduction cycle. The exocyclic amine protections are installed at a later stage (except G) to avoid the use of costly exocyclic-amine-protected counterparts that give control over protecting group manipulation. The 7'-hydroxy monomers with N-Trit/N-MMTr are then converted to the 7'-chlorophosphoramidate morpholino monomers in one step employing a combination of lithium bromide and DBU. These chlorophosphoramidate monomers are finally assembled by solid-support synthesis to obtain the short PMO oligomers.

Structure-based design of a bisphosphonate 5′(3′)-deoxyribonucleotidase inhibitor

Based on previously known inhibitor–enzyme complex structures, we developed a promising inhibitor by mimicking the phosphate ion and achieved 50- and 100-fold increases in the inhibitory potency towards cdN and mdN, respectively.

Improved protocol for the synthesis of flexibly protected morpholino monomers from unprotected ribonucleosides

An inexpensive and much improved protocol has been developed for the synthesis of protected morpholino monomers from unprotected ribonucleosides in high overall yield, using oxidative glycol cleavage and reductive amination strategy. Unlike the previous methods, the present strategy allows installing the exocyclic amine protections at a later stage, and thus avoids the use of expensive, or commercially unavailable, exocyclic amine-protected ribonucleosides as starting materials. To demonstrate the flexibility of the present method in choosing protecting groups, the monomers have been protected with several such groups of different deblocking properties at the exocyclic amine position.

Conformationally constrained nucleoside phosphonic acids – potent inhibitors of human mitochondrial and cytosolic 5′(3′)-nucleotidases

Conformationally constrained nucleoside phosphonic acids – potent inhibitors of human mitochondrial and cytosolic 5′(3′)-deoxynucleotidases.

Synthesis and properties of ApA analogues with shortened phosphonate internucleotide linkage

A complete series of the 2 '-5 ' and 3 '-5 ' regioisomeric types of r(ApA) and 2 '-d(ApA) analogues with the α-hydroxy-phosphonate C3 '-O-P-CH(OH)-C4 ″ internucleotide linkage, isopolar but non-isosteric with the phosphodiester one, were synthesized and their hybridization properties with polyU studied. Due to the chirality on the 5 '-carbon atom of the modified internucleotide linkage bearing phosphorus and hydroxy moieties, each regioisomeric type of ApA dimer is split into epimeric pairs. To examine the role of the 5 '-hydroxyl of the α-hydroxy-phosphonate moiety during hybridization, the appropriate r(ApA) analogues with 3 '(2 ')-O-P-CH(2)-C4 ″ linkage lacking the 5 '-hydroxyl were synthesized. Nuclear magnetic resonance (NMR) spectroscopy study on the conformation of the modified sugar-phosphate backbone, along with the hybridization measurements, revealed remarkable differences in the stability of complexes with polyU, depending on the 5 '-carbon atom configuration. Potential usefulness of the α-hydroxy-phosphonate linkage in modified oligoribonucleotides is discussed.

Activation of human RNase L by 2'- and 5'-O-methylphosphonate-modified oligoadenylates

To determine the influence of internucleotide linkage and sugar ring conformation, and the role of 5'-terminal phosphate, on the activation of human RNase L, a series of 2'- and 5'-O-methylphosphonate-modified tetramers were synthesized from appropriate monomeric units and evaluated for their ability to activate human RNase L. Tetramers pAAAp(c)X modified by ribo, arabino or xylo 5'-phosphonate unit p(c)X activated RNase L with efficiency comparable to that of natural activator. Moreover, incorporation of phosphonate linkages ensured the stability against cleavage by nucleases. The substitution of 5'-terminal phosphate for 5'-terminal phosphonate in tetramer p(c)XAAA afforded tetramers with excellent activation efficiency and with complete stability against cleavage by phosphomonoesterases.

Oligomerization of adenosin-5'-O-ylmethylphosphonate, an isopolar AMP analogue: evaluation of the route to short oligoadenylates

In an attempt to prepare a library of short oligoadenylate analogues featuring both the enzyme-stable internucleotide linkage and the 5'-O-methylphosphonate moiety and thus obtain a pool of potential RNase L agonists/antagonists, we studied the spontaneous polycondensation of the adenosin-5'-O-ylmethylphosphonic acid (p(c)A), an isopolar AMP analogue, and its imidazolide derivatives employing N,N'-dicyclohexylcarbodiimide under nonaqueous conditions and uranyl ions under aqueous conditions, respectively. The RP LC-MS analyses of the reaction mixtures per se, and those obtained after the periodate treatment, along with analyses and separations by capillary zone electrophoresis, allowed us to characterize major linear and cyclic oligoadenylates obtained. The structure of selected compounds was supported, after their isolation, by NMR spectroscopy. Ab initio calculation of the model structures simulating the AMP-imidazolide and p(c)A-imidazolide offered the explanation why the latter compound exerted, in contrast to AMP-imidazolide, a very low stability in aqueous solutions.

Ribo-, xylo-, and arabino-configured adenine-based nucleoside phosphonates: synthesis of monomers for solid-phase oligonucleotide assembly

Adenine-based, regioisomeric nucleoside phosphonates with ribo, xylo and arabino configuration were synthesized in the protected form suitable for the phosphotriester-like, solid-phase synthesis of oligonucleotides. Phosphonate moiety was protected by 4-methoxy-1-oxido-2-picolyl group and the furanose hydroxyl by the dimethoxytrityl group.

Study on reactivity and protection of the alpha-hydroxyphosphonate moiety in 5'-nucleotide analogues: formation of the 3'-O-P-C(OH)-C4' internucleotide linkage

The recently described epimeric nucleosidyl-5'-C-phosphonates (alpha-hydroxyphosphonates) represent novel nucleotide analogues that can be incorporated into chimeric oligonucleotides by the phosphotriester condensation method. In order to prepare suitable protected monomer(s) we have studied condensation reaction between protected 2'-deoxythymidine and 2'-deoxythymidinyl-5'-C-phosphonate, both as model compounds, in dependence on the nature of the 5'-hydroxyl protecting group. We have found that the O-acetyl group is unstable in the presence of TPSCl or MSNT used as condensing agents for activation of the phosphorus moiety. This instability negatively influences the scope of the condensation process. On the other hand, introduction of the O-methoxycarbonyl group gave excellent results. The O-methoxycarbonyl group does not participate in the condensation process, and its quantitative introduction into the nucleotide analo gues is accomplished using a novel acylating agent, methoxycarbonyl tetrazole.

Oligonucleotides with isopolar phosphonate internucleotide linkage: a new perspective for antisense compounds?

Several types of isopolar modified oligothymidylates and oligoadenylates (15 mers) with the phosphonate -O-P-CH2-O- internucleotide linkage were prepared. The modified oligonucleotides were subjected to the study of their hybridization properties, resistance against nucleases, and the ability to elicit RNase H activity.