Structural origins of the exonuclease resistance of a zwitterionic RNA

Robert Letsinger and the Evolution of Oligonucleotide Synthesis

This retrospective summarizes a presentation given at the symposium "Bob Letsinger, PhD-100 Years of History" on September 28, 2021 as part of the 17th annual meeting of the Oligonucleotide Therapeutics Society (OTS). In it I look back at my encounters with Robert Lewis Letsinger (1921-2014) while at Northwestern University as Assistant Professor between 1995 and 2000.

Influence of Sugar Modifications on the Nucleoside Conformation and Oligonucleotide Stability: A Critical Review

Ribofuranose sugar conformation plays an important role in the structure and dynamics of functional nucleic acids such as siRNAs, AONs, aptamers, miRNAs, etc. To improve their therapeutic potential, several chemical modifications have been introduced into the sugar moiety over the years. The stability of the oligonucleotide duplexes as well as the formation of stable and functional protein-oligonucleotide complexes are dictated by the conformation and dynamics of the sugar moiety. In this review, we systematically categorise various ribofuranose sugar modifications employed in DNAs and RNAs so far. We discuss different stereoelectronic effects imparted by different substituents on the sugar ring and how these effects control sugar puckering. Using this data, it would be possible to predict the precise use of chemical modifications and design novel sugar-modified nucleosides for therapeutic oligonucleotides that can improve their physicochemical properties.

Crystal structure of DNA polymerase I from Thermus phage G20c

This study describes the structure of DNA polymerase I from Thermus phage G20c, termed PolI_G20c. This is the first structure of a DNA polymerase originating from a group of related thermophilic bacteriophages infecting Thermus thermophilus, including phages G20c, TSP4, P74-26, P23-45 and phiFA and the novel phage Tth15-6. Sequence and structural analysis of PolI_G20c revealed a 3'-5' exonuclease domain and a DNA polymerase domain, and activity screening confirmed that both domains were functional. No functional 5'-3' exonuclease domain was present. Structural analysis also revealed a novel specific structure motif, here termed SβαR, that was not previously identified in any polymerase belonging to the DNA polymerases I (or the DNA polymerase A family). The SβαR motif did not show any homology to the sequences or structures of known DNA polymerases. The exception was the sequence conservation of the residues in this motif in putative DNA polymerases encoded in the genomes of a group of thermophilic phages related to Thermus phage G20c. The structure of PolI_G20c was determined with the aid of another structure that was determined in parallel and was used as a model for molecular replacement. This other structure was of a 3'-5' exonuclease termed ExnV1. The cloned and expressed gene encoding ExnV1 was isolated from a thermophilic virus metagenome that was collected from several hot springs in Iceland. The structure of ExnV1, which contains the novel SβαR motif, was first determined to 2.19 Å resolution. With these data at hand, the structure of PolI_G20c was determined to 2.97 Å resolution. The structures of PolI_G20c and ExnV1 are most similar to those of the Klenow fragment of DNA polymerase I (PDB entry 2kzz) from Escherichia coli, DNA polymerase I from Geobacillus stearothermophilus (PDB entry 1knc) and Taq polymerase (PDB entry 1bgx) from Thermus aquaticus.

Structural dynamics and determinants of 2-aminoadenine specificity in DNA polymerase DpoZ of vibriophage ϕVC8

All genetic information in cellular life is stored in DNA copolymers composed of four basic building blocks (ATGC-DNA). In contrast, a group of bacteriophages belonging to families Siphoviridae and Podoviridae has abandoned the usage of one of them, adenine (A), replacing it with 2-aminoadenine (Z). The resulting ZTGC-DNA is more stable than its ATGC-DNA counterpart, owing to the additional hydrogen bond present in the 2-aminoadenine:thymine (Z:T) base pair, while the additional amino group also confers resistance to the host endonucleases. Recently, two classes of replicative proteins found in ZTGC-DNA-containing phages were characterized and one of them, DpoZ from DNA polymerase A (PolA) family, was shown to possess significant Z-vs-A specificity. Here, we present the crystallographic structure of the apo form of DpoZ of vibriophage ϕVC8, composed of the 3′-5′ exonuclease and polymerase domains. We captured the enzyme in two conformations that involve the tip of the thumb subdomain and the exonuclease domain. We highlight insertions and mutations characteristic of ϕVC8 DpoZ and its close homologues. Through mutagenesis and functional assays we suggest that the preference of ϕVC8 DpoZ towards Z relies on a polymerase backtracking process, more efficient when the nascent base pair is A:T than when it is Z:T.

A Study on Synthesis and Upscaling of 2'-O-AECM-5-methyl Pyrimidine Phosphoramidites for Oligonucleotide Synthesis

2'-O-(N-(Aminoethyl)carbamoyl)methyl-modified 5-methyluridine (AECM-MeU) and 5-methylcytidine (AECM-MeC) phosphoramidites are reported for the first time and prepared in multigram quantities. The syntheses of AECM-MeU and AECM-MeC nucleosides are designed for larger scales (approx. 20 g up until phosphoramidite preparation steps) using low-cost reagents and minimizing chromatographic purifications. Several steps were screened for best conditions, focusing on the most crucial steps such as N3 and/or 2'-OH alkylations, which were improved for larger scale synthesis using phase transfer catalysis (PTC). Moreover, the need of chromatographic purifications was substantially reduced by employing one-pot synthesis and improved work-up strategies.

Cationic oligonucleotide derivatives and conjugates: A favorable approach for enhanced DNA and RNA targeting oligonucleotides

Antisense oligonucleotides (ASOs) have the ability of binding to endogenous nucleic acid targets, thereby inhibiting the gene expression. Although ASOs have great potential in the treatment of many diseases, the search for favorable toxicity profiles and distribution has been challenging and consequently impeded the widespread use of ASOs as conventional medicine. One strategy that has been employed to optimize the delivery profile of ASOs, is the functionalization of ASOs with cationic amine groups, either by direct conjugation onto the sugar, nucleobase or internucleotide linkage. The introduction of these positively charged groups has improved properties like nuclease resistance, increased binding to the nucleic acid target and improved cell uptake for oligonucleotides (ONs) and ASOs. The modifications highlighted in this review are some of the most prevalent cationic amine groups which have been attached as single modifications onto ONs/ASOs. The review has been separated into three sections, nucleobase, sugar and backbone modifications, highlighting what impact the cationic amine groups have on the ONs/ASOs physiochemical and biological properties. Finally, a concluding section has been added, summarizing the important knowledge from the three chapters, and examining the future design for ASOs.

Chemical Synthesis of Modified Oligonucleotides Containing 5'-Amino-5'-Deoxy-5'-Hydroxymethylthymidine Residues

Introduction of cationic modifications into an oligonucleotide can increase its nuclease resistance and duplex- or triplex-forming abilities. In a recent study, we found that the nuclease resistance and RNA binding selectivity of an oligonucleotide containing a 5'-(R)-amino-5'-deoxy-5'-(R)-hydroxymethylthymidine residue were greater than those of the unmodified oligonucleotide. In this article, we describe the synthesis of 5'-amino-5'-deoxy-5'-hydroxymethylthymidine via dihydroxylation of the 5'-alkene derivative using either of two commercial AD (asymmetric dehydroxylation) mixes or via epoxidation and ring opening. We also provide detailed protocols for the syntheses of oligonucleotides containing 5'-amino-5'-deoxy-5'-hydroxymethylthymidine residues. © 2021 Wiley Periodicals LLC. Basic Protocol 1: Synthesis of 5'-amino-5'-deoxy-5'-hydroxymethylthymidine phosphoramidites 9a and 9b Basic Protocol 2: Synthesis of oligonucleotides 1 and 2 containing 5'-amino-5'-deoxy-5'-hydoxymethylthymidine residues (_R T and _S T).

Synthesis, chirality-dependent conformational and biological properties of siRNAs containing 5'-(R)- and 5'-(S)-C-methyl-guanosine

Various chemical modifications have been identified that enhance potency of small interfering RNAs (siRNAs) and that reduce off-target effects, immune stimulation, and toxicities of metabolites of these therapeutic agents. We previously described 5′-C-methyl pyrimidine nucleotides also modified at the 2′ position of the sugar. Here, we describe the synthesis of 2′-position unmodified 5′-(R)- and 5′-(S)-C-methyl guanosine and evaluation of these nucleotides in the context of siRNA. The (R) isomer provided protection from 5′ exonuclease and the (S) isomer provided protection from 3′ exonuclease in the context of a terminally modified oligonucleotide. siRNA potency was maintained when these modifications were incorporated at the tested positions of sense and antisense strands. Moreover, the corresponding 5′ triphosphates were not substrates for mitochondrial DNA polymerase. Models generated based on crystal structures of 5′ and 3′ exonuclease oligonucleotide complexes with 5′-(R)- and 5′-(S)-C-methyl substituents attached to the 5′- and 3′-terminal nucleotides, respectively, provided insight into the origins of the observed protections. Structural properties of 5′-(R)-C-methyl guanosine incorporated into an RNA octamer were analysed by X-ray crystallography, and the structure explains the loss in duplex thermal stability for the (R) isomer compared with the (S) isomer. Finally, the effect of 5′-C-methylation on endoribonuclease activity has been explained.

Expression and functional study of VpV262 Pol, a moderately halophilic DNA polymerase from the Vibrio parahaemolyticus phage VpV262

Halophilic organisms are found widely in environments where the salt concentration is higher than 0.2 M. Halophilic proteins isolated from these organisms maintain structural integrity and function under high salt stress, whereas their non-halophilic homologs tend to aggregate and collapse. Here we report for the first time the expression and function of a DNA polymerase (DNAPol) VpV262 Pol, which belongs to DNAPol Family A from Vibrio parahaemolyticus phage VpV262. Enzymatic activity assay revealed that VpV262 Pol possessed 5'-3' polymerase activity as well as 3'-5' proofreading exonuclease activity. VpV262 Pol requires Mg²⁺ or Mn²⁺ to catalyze the polymerization reaction. Polymerization activity assay under a wide range of salt concentrations showed that VpV262 Pol maintains the highest polymerase activity with 0-0.3 M of NaCl/KCl and 0-0.5 M KAc (potassium acetate) /KGlc (potassium gluconate) when treated with 0-1 M corresponding salts, in contrast to significantly decreased activity of Phi29 Pol and Taq Pol above 0.2 M. Consistent with typical features of other halophilic proteins, negatively-charged amino acids are more frequently distributed on the surface of VpV262 Pol, contributing to highly solubility and enhanced halotolerance. While 3D-Structure of VpV262 Pol needs to be confirmed by experimental data further, this study here has added a member for the relatively small family of halotolerant DNA polymerase, and provides a valuable reference in isolation and characterization of DNA polymerases from halophilic organisms.

Chemical synthesis and properties of modified oligonucleotides containing 5'-amino-5'-deoxy-5'-hydroxymethylthymidine residues

In this study, we designed 5'-amino-5'-deoxy-5'-hydroxymethylthymidine as a new oligonucleotide modification with an amino group directly attached to the 5'-carbon atom. We successfully synthesized two isomers of 5'-amino-5'-deoxy-5'-hydroxymethylthymidine via dihydroxylation of the 5'-vinyl group incorporated into 5'-deoxy-5'-C-methenylthymidine derivative. Moreover, it was found that the nuclease resistance, binding selectivity to single-stranded RNA, and triplex-forming ability of an oligonucleotide containing _RT residues of the new compound were higher than those of the unmodified oligonucleotide.

Modification of oligonucleotides with weak basic residues via the 2'-O-carbamoylethyl linker for improving nuclease resistance without loss of duplex stability and antisense activity

For the improvement of nuclease resistance, four kinds of new modifications through a carbamoylethyl linker were designed. Among them, the 2'-O-[2-N-{2-(benzimidazol-1-yl)ethyl}carbamoylethyl] modification showed 20-fold longer half-life when treated with a 3' to 5' exonuclease compared to the 2'-O-methoxyethyl (MOE) modification, which is used in approved drugs. In addition, this large modification did not disturb the binding affinity or RNase H-dependent antisense activity. From these findings, it could be concluded that an adequate linker, such as carbamoylethyl in this study, could extend the utility of 2'-O-modification without loss of the properties of nucleic acids. This strategy would be useful for the development of nucleic acid therapeutics.

Chemical methods for the modification of RNA

RNA is often considered as being the vector for the transmission of genetic information from DNA to the protein synthesis machinery. However, besides translation RNA participates in a broad variety of fundamental biological roles such as gene expression and regulation, protein synthesis, and even catalysis of chemical reactions. This variety of function combined with intricate three-dimensional structures and the discovery of over 100 chemical modifications in natural RNAs require chemical methods for the modification of RNAs in order to investigate their mechanism, location, and exact biological roles. In addition, numerous RNA-based tools such as ribozymes, aptamers, or therapeutic oligonucleotides require the presence of additional chemical functionalities to strengthen the nucleosidic backbone against degradation or enhance the desired catalytic or binding properties. Herein, the two main methods for the chemical modification of RNA are presented: solid-phase synthesis using phosphoramidite precursors and the enzymatic polymerization of nucleoside triphosphates. The different synthetic and biochemical steps required for each method are carefully described and recent examples of practical applications based on these two methods are discussed.

A versatile post-synthetic method on a solid support for the synthesis of RNA containing reduction-responsive modifications

An original post-synthetic method on a solid support was developed to introduce various disulfide bond containing groups at the 2'-OH of oligoribonucleotides (RNAs). It is based on a thiol disulfide exchange reaction between several readily accessible alkyldisulfanyl-pyridine derivatives and 2'-O-acetylthiomethyl RNA in the presence of butylamine. By this strategy, diverse 2'-O-alkyldithiomethyl RNAs were obtained. These modifications provided high nuclease resistance to RNA and were easily removed with glutathione treatment, thus featuring a potential use for siRNA prodrugs.

Structural Basis of Duplex Thermodynamic Stability and Enhanced Nuclease Resistance of 5'-C-Methyl Pyrimidine-Modified Oligonucleotides

Although judicious use of chemical modifications has contributed to the success of nucleic acid therapeutics, poor systemic stability remains a major hurdle. The introduction of functional groups around the phosphate backbone can enhance the nuclease resistance of oligonucleotides (ONs). Here, we report the synthesis of enantiomerically pure (R)- and (S)-5'-C-methyl (C5'-Me) substituted nucleosides and their incorporation into ONs. These modifications generally resulted in a decrease in thermal stability of oligonucleotide (ON) duplexes in a manner dependent on the stereoconfiguration at C5' with greater destabilization characteristic of (R)-epimers. Enhanced stability against snake venom phosphodiesterase resulted from modification of the 3'-end of an ON with either (R)- or (S)-C5'-Me nucleotides. The (S)-isomers with different 2'-substituents provided greater resistance against 3'-exonucleases than the corresponding (R)-isomers. Crystal structure analyses of RNA octamers with (R)- or (S)-5'-C-methyl-2'-deoxy-2'-fluorouridine [(R)- or (S)-C5'-Me-2'-FU, respectively] revealed that the stereochemical orientation of the C5'-Me and the steric effects that emanate from the alkyl substitution are the dominant determinants of thermal stability and are likely molecular origins of resistance against nucleases. X-ray and NMR structural analyses showed that the (S)-C5'-Me epimers are spatially and structurally more similar to their natural 5' nonmethylated counterparts than the corresponding (R)-epimers.

Nuclease resistant oligonucleotides with cell penetrating properties

2'-O-AECM modified oligonucleotides provide an unusual combination of remarkable properties. This includes the combination of high resistance towards enzymatic degradation and the spontaneous cellular uptake of AECM oligonucleotides.

Polyamine-oligonucleotide conjugates: a promising direction for nucleic acid tools and therapeutics

Chemical modification and/or the conjugation of small functional molecules to oligonucleotides have significantly improved their biological and biophysical properties, addressing issues such as poor cell penetration, stability to nucleases and low affinity for their targets. Here, the authors review the literature reporting on the biophysical, biochemical and biological properties of one particular class of modification - polyamine-oligonucleotide conjugates. Naturally derived and synthetic polyamines have been grafted onto a variety of oligonucleotide formats, including antisense oligonucleotides and siRNAs. In many cases this has had beneficial effects on their properties such as target hybridization, nuclease resistance, cellular uptake and activity. Polyamine-oligonucleotide conjugation, therefore, represents a promising direction for the further development of oligonucleotide-based therapeutics and tools.

Synthesis, binding, nuclease resistance and cellular uptake properties of 2'-O-acetalester-modified oligonucleotides containing cationic groups

We report on the synthesis and properties of oligonucleotides (ONs) with 2'-O-acetalester modifications containing cationic side chains in a prodrug-like approach. In the aim to improve cell penetration and nuclease resistance, various different amino- or guanidino-acetalester were grafted to 2'-OH of uridine and the corresponding phosphoramidites were incorporated into ONs. Introduction of 2'-O-(2-aminomethyl-2-ethyl)butyryloxymethyl (AMEBuOM) modification into 2'-OMe ONs leads to high resistance towards enzymatic degradation and to destabilization of duplexes with complementary RNA strand. Spontaneous uptake experiments of a twelve-mer containing ten 2'-O-AMEBuOM-U units into A673 cells showed moderate internalization of ON within the cells whereas substantial internalization of the corresponding lipophilic 2'-O-pivaloyloxymethyl ON was observed for the first time.

Antisense oligonucleotides in therapy for neurodegenerative disorders

Antisense oligonucleotides are synthetic single stranded strings of nucleic acids that bind to RNA and thereby alter or reduce expression of the target RNA. They can not only reduce expression of mutant proteins by breakdown of the targeted transcript, but also restore protein expression or modify proteins through interference with pre-mRNA splicing. There has been a recent revival of interest in the use of antisense oligonucleotides to treat several neurodegenerative disorders using different approaches to prevent disease onset or halt disease progression and the first clinical trials for spinal muscular atrophy and amyotrophic lateral sclerosis showing promising results. For these trials, intrathecal delivery is being used but direct infusion into the brain ventricles and several methods of passing the blood brain barrier after peripheral administration are also under investigation.

Synthesis and properties of oligonucleotides modified with 2'-O-(2-carboxyethyl)nucleotides and their carbamoyl derivatives

2'-O-Methyl oligoribonucleotides with four kinds of 2'-O-modified uridine derivatives were synthesised. Their duplex stability, hydration behavior and exonuclease resistance were studied by spectroscopic analyses and molecular dynamics simulations. Consequently, 2'-O-modification of the uridine residue with 2-carbamoylethyl or 2-(N-methylcarbamoyl)ethyl groups resulted in a significant improvement of the exonuclease resistance without the loss of duplex stability.

HoLaMa: A Klenow sub-fragment lacking the 3'-5' exonuclease domain

The design, construction, overexpression, and purification of a Klenow sub-fragment lacking the 3'-5' exonuclease domain is presented here. In particular, a synthetic gene coding for the residues 515-928 of Escherichia coli DNA polymerase I was constructed. To improve the solubility and stability of the corresponding protein, the synthetic gene was designed to contain 11 site-specific substitutions. The gene was inserted into the pBADHis expression vector, generating 2 identical Klenow sub-fragments, bearing or not a hexahistidine tag. Both these Klenow sub-fragments, denominated HoLaMa and HoLaMaHis, were purified, and their catalytic properties were compared to those of Klenow enzyme. When DNA polymerase activity was assayed under processive conditions, the Klenow enzyme performed much better than HoLaMa and HoLaMaHis. However, when DNA polymerase activity was assayed under distributive conditions, the initial velocity of the reaction catalyzed by HoLaMa was comparable to that observed in the presence of Klenow enzyme. In particular, under distributive conditions HoLaMa was found to strongly prefer dsDNAs bearing a short template overhang, to the length of which the Klenow enzyme was relatively insensitive. Overall, our observations indicate that the exonuclease domain of the Klenow enzyme, besides its proofreading activity, does significantly contribute to the catalytic efficiency of DNA elongation.

Crystal structure, stability and Ago2 affinity of phosphorodithioate-modified RNAs

The high Ago2 affinity of siRNAs with combined 2′-O-methyl and phosphorodithioate backbone modifications (MePS2) in the 3′-terminal region of the sense strand is likely the result of enhanced hydrophobic interactions with the protein's PAZ domain.

Enhanced splice correction by 3', 5'-serinol and 2'-(ω-O-methylserinol) guarded OMe-RNA/DNA mixmers in cells

Development of artificial nucleic acids for therapeutic applications warrants that the oligomers be endowed with high specificity, enzymatic stability and with no/reduced off-target effects. The balance between strength of the duplex with target RNA and enzyme stability is therefore the key factor for the designed modification. The chiral serinol derivative combines the attributes of amino- and methoxy- substitution when at 2'- position and at 3'- and 5'- ends, effectively balancing the duplex stability and resistance to hydrolytic enzymes. The biological effect seen is the remarkable improvement in splice correction by the steric blocking antisense oligonucleotide with just 4 modified units, i.e ~20% substitution with R-aminomethoxypropyloxy (R-AMP)-thymidine within the 2'-OMe 18mer sequence.

Insights into the roles of desolvation and π-electron interactions during DNA polymerization

This report describes the use of several isosteric non-natural nucleotides as probes to evaluate the roles of nucleobase shape, size, solvation energies, and π-electron interactions as forces influencing key kinetic steps of the DNA polymerization cycle. Results are provided using representative high- and low-fidelity DNA polymerases. Results generated with the E. coli Klenow fragment reveal that this high-fidelity polymerase utilizes hydrophobic nucleotide analogues with higher catalytic efficiencies compared to hydrophilic analogues. These data support a major role for nucleobase desolvation during nucleotide selection and insertion. In contrast, the low-fidelity HIV-1 reverse transcriptase discriminates against hydrophobic analogues and only tolerates non-natural nucleotides that are capable of hydrogen-bonding or π-stacking interactions. Surprisingly, hydrophobic analogues that function as efficient substrates for the E. coli Klenow fragment behave as noncompetitive or uncompetitive inhibitors against HIV-1 reverse transcriptase. In these cases, the mode of inhibition depends upon the absence or presence of a templating nucleobase. Molecular modeling studies suggest that these analogues bind to the active site of reverse transcriptase as well as to a nearby hydrophobic binding pocket. Collectively, the studies using these non-natural nucleotides reveal important mechanistic differences between representative high- and low-fidelity DNA polymerases during nucleotide selection and incorporation.

Functionalization of the 3'-ends of DNA and RNA strands with N-ethyl-N-coupled nucleosides: a promising approach to avoid 3'-exonuclease-catalyzed hydrolysis of therapeutic oligonucleotides

The development of nucleic acid derivatives to generate novel medical treatments has become increasingly popular, but the high vulnerability of oligonucleotides to nucleases limits their practical use. We explored the possibility of increasing the stability against 3'-exonucleases by replacing the two 3'-terminal nucleotides by N-ethyl-N-coupled nucleosides. Molecular dynamics simulations of 3'-N-ethyl-N-modified DNA:Klenow fragment complexes suggested that this kind of alteration has negative effects on the correct positioning of the adjacent scissile phosphodiester bond at the active site of the enzyme, and accordingly was expected to protect the oligonucleotide from degradation. We verified that these modifications conferred complete resistance to 3'-exonucleases. Furthermore, cellular RNAi experiments with 3'-N-ethyl-N-modified siRNAs showed that these modifications were compatible with the RNAi machinery. Overall, our experimental and theoretical studies strongly suggest that these modified oligonucleotides could be valuable for therapeutic applications.

Synthesis and antisense properties of fluoro cyclohexenyl nucleic acid (F-CeNA), a nuclease stable mimic of 2'-fluoro RNA

We report the design and synthesis of 2'-fluoro cyclohexenyl nucleic acid (F-CeNA) pyrimidine phosphoramidites and the synthesis and biophysical, structural, and biological evaluation of modified oligonucleotides. The synthesis of the nucleoside phosphoramidites was accomplished in multigram quantities starting from commercially available methyl-D-mannose pyranoside. Installation of the fluorine atom was accomplished using nonafluorobutanesulfonyl fluoride, and the cyclohexenyl ring system was assembled by means of a palladium-catalyzed Ferrier rearrangement. Installation of the nucleobase was carried out under Mitsunobu conditions followed by standard protecting group manipulations to provide the desired pyrimidine phosphoramidites. Biophysical evaluation indicated that F-CeNA shows behavior similar to that of a 2'-modified nucleotide, and duplexes with RNA showed slightly lower duplex thermostability as compared to that of the more rigid 3'-fluoro hexitol nucleic acid (FHNA). However, F-CeNA modified oligonucleotides were significantly more stable against digestion by snake venom phosphodiesterases (SVPD) as compared to unmodified DNA, 2'-fluoro RNA (FRNA), 2'-methoxyethyl RNA (MOE), and FHNA modified oligonucleotides. Examination of crystal structures of a modified DNA heptamer duplex d(GCG)-T*-d(GCG):d(CGCACGC) by X-ray crystallography indicated that the cyclohexenyl ring system exhibits both the (3)H(2) and (2)H(3) conformations, similar to the C3'-endo/C2'-endo conformation equilibrium seen in natural furanose nucleosides. In the (2)H(3) conformation, the equatorial fluorine engages in a relatively close contact with C8 (2.94 Å) of the 3'-adjacent dG nucleotide that may represent a pseudo hydrogen bond. In contrast, the cyclohexenyl ring of F-CeNA was found to exist exclusively in the (3)H(2) (C3'-endo like) conformation in the crystal structure of the modified A-form DNA decamer duplex [d(GCGTA)-T*-d(ACGC)](2.) In an animal experiment, a 16-mer F-CeNA gapmer ASO showed similar RNA affinity but significantly improved activity compared to that of a sequence matched MOE ASO, thus establishing F-CeNA as a useful modification for antisense applications.

Synthesis, gene silencing, and molecular modeling studies of 4'-C-aminomethyl-2'-O-methyl modified small interfering RNAs

The linear syntheses of 4'-C-aminomethyl-2'-O-methyl uridine and cytidine nucleoside phosphoramidites were achieved using glucose as the starting material. The modified RNA building blocks were incorporated into small interfering RNAs (siRNAs) by employing solid phase RNA synthesis. Thermal melting studies showed that the modified siRNA duplexes exhibited slightly lower T(m) (∼1 °C/modification) compared to the unmodified duplex. Molecular dynamics simulations revealed that the 4'-C-aminomethyl-2'-O-methyl modified nucleotides adopt South-type conformation in a siRNA duplex, thereby altering the stacking and hydrogen-bonding interactions. These modified siRNAs were also evaluated for their gene silencing efficiency in HeLa cells using a luciferase-based reporter assay. The results indicate that the modifications are well tolerated in various positions of the passenger strand and at the 3' end of the guide strand but are less tolerated in the seed region of the guide strand. The modified siRNAs exhibited prolonged stability in human serum compared to unmodified siRNA. This work has implications for the use of 4'-C-aminomethyl-2'-O-methyl modified nucleotides to overcome some of the challenges associated with the therapeutic utilities of siRNAs.

Synthesis and properties of cationic 2'-O-[N-(4-aminobutyl)carbamoyl] modified oligonucleotides

2'-O-[N-(4-Aminobutylcarbamoyl)]uridine (U(abcm)) was synthesized and incorporated into oligonucleotides. The oligonucleotides incorporating U(abcm) formed more stable duplexes with their complementary and mismatched RNAs than those containing 2'-O-carbamoyluridine (U(cm)). The stability of duplex with a U(abcm)-rG base pair showed higher thermostability than the duplex having unmodified U-rG base pair. The U(abcm) residue showed enhanced resistance to snake venome phosphodiesterase.

Synthesis of 2'-O-guanidinopropyl-modified nucleoside phosphoramidites and their incorporation into siRNAs targeting hepatitis B virus

Synthetic RNAi activators have shown considerable potential for therapeutic application to silencing of pathology-causing genes. Typically these exogenous RNAi activators comprise duplex RNA of approximately 21 bp with 2 nt overhangs at the 3' ends. To improve efficacy of siRNAs, chemical modification at the 2'-OH group of ribose has been employed. Enhanced stability, gene silencing and attenuated immunostimulation have been demonstrated using this approach. Although promising, efficient and controlled delivery of highly negatively charged nucleic acid gene silencers remains problematic. To assess the potential utility of introducing positively charged groups at the 2' position, our investigations aimed at assessing efficacy of novel siRNAs containing 2'-O-guanidinopropyl (GP) moieties. We describe the formation of all four GP-modified nucleosides using the synthesis sequence of Michael addition with acrylonitrile followed by Raney-Ni reduction and guanidinylation. These precursors were used successfully to generate antihepatitis B virus (HBV) siRNAs. Testing in a cell culture model of viral replication demonstrated that the GP modifications improved silencing. Moreover, thermodynamic stability was not affected by the GP moieties and their introduction into each position of the seed region of the siRNA guide strand did not alter the silencing efficacy of the intended HBV target. These results demonstrate that modification of siRNAs with GP groups confers properties that may be useful for advancing therapeutic application of synthetic RNAi activators.

Why Carba-LNA-modified oligonucleotides show considerably improved 3'-exonuclease stability compared to that of the LNA modified or the native counterparts: A Michaelis-Menten kinetic analysis

In this study, 12 different native or LNA, carba-LNA-modified dinucleoside phosphates were designed as simple chemical models to study how carba-LNA modifications improve the 3'-exonuclease (SVPDE in this study) resistance of internucleotidic phosphate compared to those exhibited by LNA-modified and the native counterparts. Michaelis-Menten kinetic studies for dimers 3 - 7, in which the LNA or carba-LNA modifications are located at the 5'-end, showed that (i) increased 3'-exonuclease resistance of (5')[LNA-T](p)T (3) compared to the native (5')T(p)T (1) was mainly attributed to steric hindrance imposed by the LNA modification that retards the nuclease binding (K(M)) and (ii) digestion of (5')[carba-LNA-dT](p)T (4) and (5')[LNA-T](p)T (3), however, exhibit similar K(M)s, whereas the former shows a 100x decrease in K(cat) and is hence more stable than the latter. By studying the correlation between log k(cat) and pK(a) of the departing 3'(or 6')-OHs for 3-7, we found the pK(a) of 3'-OH of carba-LNA-T was 1.4 pK(a) units higher than that of LNA-T, and this relatively less acidic character of the 3'-OH in the former leads to the 100x decrease in the catalytic efficiency for the digestion of (5')[carba-LNA-T](p)T (4). In contrast, Michaelis-Menten kinetic studies for dimers 9-12, with the LNA or carba-LNA modifications at the 3'-end, showed that the digestion of (5')T(p)[LNA-T] (9) exhibited similar K(M) but k(cat) decreased around 40 times compared to that of the native (5')T(p)T (1). Similar k(cat) values have been observed for digestion of (5')T(p)[carba-LNA-T] (10) and (5')T(p)[LNA-T] (9). The higher stability of carba-LNA modified dimer 10 compared with LNA modified dimer 9 comes solely from the increased K(M).

Crystallographic studies of chemically modified nucleic acids: a backward glance

Chemically modified nucleic acids (CNAs) are widely explored as antisense oligonucleotide or small interfering RNA (siRNA) candidates for therapeutic applications. CNAs are also of interest in diagnostics, high-throughput genomics and target validation, nanotechnology and as model systems in investigations directed at a better understanding of the etiology of nucleic acid structure, as well as the physicochemical and pairing properties of DNA and RNA, and for probing protein-nucleic acid interactions. In this article, we review research conducted in our laboratory over the past two decades with a focus on crystal-structure analyses of CNAs and artificial pairing systems. We highlight key insights into issues ranging from conformational distortions as a consequence of modification to the modulation of pairing strength, and RNA affinity by stereoelectronic effects and hydration. Although crystal structures have only been determined for a subset of the large number of modifications that were synthesized and analyzed in the oligonucleotide context to date, they have yielded guiding principles for the design of new analogs with tailor-made properties, including pairing specificity, nuclease resistance, and cellular uptake. And, perhaps less obviously, crystallographic studies of CNAs and synthetic pairing systems have shed light on fundamental aspects of DNA and RNA structure and function that would not have been disclosed by investigations solely focused on the natural nucleic acids.

Synthesis of conformationally locked Carba-LNAs through intramolecular free-radical addition to C=N. Electrostatic and steric implication of the carba-LNA substituents in the modified oligos for nuclease and thermodynamic stabilities

The syntheses of the hitherto unavailable parent fully unsubstituted carba-LNA and its C7'-amino and/or C6'-hydroxyl substituted derivatives, have been accomplished by the intramolecular 5-exo free-radical addition to a C4'-tethered C=N to give carba-LNAs with variable hydrophilic substituents at C6'/C7' (amino and/or hydroxyl). They have been introduced into isosequential antisense oligonucleotides (AONs) to examine how their relative electrostatic and steric effects in the minor groove of a putative AON-RNA duplex affect the target affinity, nuclease resistance, and RNase H elicitation. We show that 2'-oxygen in LNA is important in stabilizing the DNA/DNA and DNA/RNA duplexes vis-a-vis the unsubstituted carba-LNA and its other derivatives and that hydrophobic groups at C6'/C7' in both carba-LNA and carba-ENA relatively destabilize the AON/DNA duplex more profoundly than those in the AON/RNA duplexes. Two main factors affect the relative stabilities of AON/DNA versus AON/RNA duplexes: (i) hydration in the minor groove depending upon hydrophilicity vis-a-vis hydrophobicity of the substituents, and (ii) the relative size of the minor groove in the AON/DNA versus AON/RNA duplexes dictates the steric clash with the substituents depending upon their relative chiralities. We also show how the chirality and chemical nature of the C6'/C7' substituents affect the nuclease stability as well as the thermal stability and the RNase recruitment by AON/RNA duplexes.

Inhibitors interacting with the magnesium binding site of reverse transcriptase: synthesis and biological activity studies of 3'-(omega-amino-acyl) amino-3'-deoxy-thymidine

Active site of reverse transcriptase contains carboxylate groups involved in the magnesium binding. We prepared some nucleoside analogs which could bind to these carboxylates preventing the binding of nucleotides. To the 3'-amino-3'-deoxy-thymidine, different N-protected omega-amino-acids were bound, the protection removed to give the 3'-(omega-amino-acyl-) amino-3'-deoxy-thymidines in good yield. Some showed moderate to low activity in HIV 1 replication test.

Chemical synthesis of diastereomeric diadenosine boranophosphates (ApbA) from 2'-O-(2-cyanoethoxymethyl)adenosine by the boranophosphotriester method

We have synthesized diastereomerically pure diadenosine 3',5'-boranophosphates (Ap(b)A) by using the boranophosphotriester method from ribonucleosides protected with the 2'-hydroxy protecting group 2-cyanoethoxymethyl (CEM). Melting curves of the triple-helical complex of the dimer Ap(b)A and 2poly(U) at high ionic strength revealed that presumptive (Sp)-Ap(b)A had a much higher affinity and presumptive (Rp)-Ap(b)A a much lower affinity for poly(U) than the natural dimer ApA did. In contrast, the affinities of these dimers for poly(dT) were similar. Both the (Rp)- and the (Sp)-boranophosphate diastereomers showed much higher resistance to digestion by snake venom phosphodiesterase and nuclease P1 than ApA did. They have potential for use as synthons to be incorporated into boranophosphate oligonucleotides. In particular, because oligonucleotides containing Sp boranophosphate nucleotides are expected to bind more strongly and specifically to RNA than natural oligoribonucleotides do, they may find application in the isolation and detection of functional RNA in basic research and diagnostics.

2'-O-Lysylaminohexyl oligonucleotides: modifications for antisense and siRNA

A novel type of oligonucleotide has been developed, characterized by the attachment of a lysyl moiety to a 2'-O-aminohexyl linker. A protected lysine building block was tethered to 2'-O-aminohexyluridine, and the product was converted into the corresponding phosphoramidite. Up to six modified nucleosides were incorporated in dodecamer DNA and RNA oligonucleotides using standard phosphoramidite chemistry. Each of the building blocks contributes one positive charge to the oligonucleotide instead of the negative charge of a wild-type nucleotide. Thermal denaturation profiles indicated a stabilizing effect of 2'-O-lysylaminohexyl chains that was more pronounced in RNA duplexes. Incubation of the oligonucleotides with 5'-exonuclease revealed an exceptionally high stability against enzymatic degradation. Incorporation of up to three modifications into functional antisense and siRNA oligonucleotides targeted at ICAM-1 showed that the gene-silencing activity was higher with an increasing number of lysylaminohexyl nucleotides. Compared with wild-type antisense or siRNA, compounds with three modifications led to equal or higher ICAM-1 downregulation.

Crystal structure of tricyclo-DNA: an unusual compensatory change of two adjacent backbone torsion angles

The crystal structure of a DNA duplex with tricyclo-DNA (tc-DNA) residues explains the increased RNA affinity of tc-DNA relative to DNA and tc-DNA's superior resistance to nucleases.

Insights from crystallographic studies into the structural and pairing properties of nucleic acid analogs and chemically modified DNA and RNA oligonucleotides

Chemically modified nucleic acids function as model systems for native DNA and RNA; as chemical probes in diagnostics or the analysis of protein-nucleic acid interactions and in high-throughput genomics and drug target validation; as potential antigene-, antisense-, or RNAi-based drugs; and as tools for structure determination (i.e., crystallographic phasing), just to name a few. Biophysical and structural investigations of chemically modified DNAs and RNAs, particularly of nucleic acid analogs with more significant alterations to the well-known base-sugar-phosphate framework (i.e., peptide or hexopyranose nucleic acids), can also provide insights into the properties of the natural nucleic acids that are beyond the reach of studies focusing on DNA or RNA alone. In this review we summarize results from crystallographic analyses of chemically modified DNAs and RNAs that are primarily of interest in the context of the discovery and development of oligonucleotide-based therapeutics. In addition, we re-examine recent structural data on nucleic acid analogs that are investigated as part of a systematic effort to rationalize nature's choice of pentose in the genetic system.

Five- and six-membered conformationally locked 2',4'-carbocyclic ribo-thymidines: synthesis, structure, and biochemical studies

Two unusual reactions involving the 5-hexenyl or the 6-heptenyl radical cyclization of a distant double bond at C4' and the radical center at C2' of the ribofuranose ring of thymidine have been used as key steps to synthesize North-type conformationally constrained cis-fused bicyclic five-membered and six-membered carbocyclic analogues of LNA (carbocyclic-LNA-T) and ENA (carbocyclic-ENA-T) in high yields. Their structures have been confirmed unambiguously by long range 1H-13C NMR correlation (HMBC), TOCSY, COSY, and NOE experiments. The carbocyclic-LNA-T and carbocyclic-ENA-T were subsequently incorporated into the antisense oligonucleotides (AONs) to show that they enhance the Tm of the modified AON/RNA heteroduplexes by 3.5-5 degrees C and 1.5 degrees C/modification for carbocyclic-LNA-T and carbocyclic-ENA-T, respectively. Whereas the relative RNase H cleavage rates with carbocyclic-LNA-T, carbocyclic-ENA-T, aza-ENA-T, and LNA-T modified AON/RNA duplexes were found to be very similar to that of the native counterpart, irrespective of the type and the site modification in the AON strand, a single incorporation of carbocyclic-LNA and carbocyclic-ENA into AONs leads to very much more enhanced nuclease stability in the blood serum (stable >48 h) as compared to that of the native (fully degraded <3 h) and the LNA-modified AONs (fully degraded <9 h) and aza-ENA ( approximately 85% stable in 48 h). Clearly, remarkably enhanced lifetimes of these carbocyclic-modified AONs in the blood serum may produce the highly desired pharmacokinetic properties because of their unique stability and consequently a net reduction of the required dosage. This unique quality as well as their efficient use as the AON in the RNase H-promoted cleavage of the target RNA makes our carbocyclic-LNA and carbocyclic-ENA modifications excellent candidates as potential antisense therapeutic agents.

Crystal structures of DNA:DNA and DNA:RNA duplexes containing 5-(N-aminohexyl)carbamoyl-modified uracils reveal the basis for properties as antigene and antisense molecules

Oligonucleotides containing 5-(N-aminohexyl)carbamoyl-modified uracils have promising features for applications as antigene and antisense therapies. Relative to unmodified DNA, oligonucleotides containing 5-(N-aminohexyl)carbamoyl-2′-deoxyuridine (^NU) or 5-(N-aminohexyl)carbamoyl-2′-O-methyluridine (^NU_m), respectively exhibit increased binding affinity for DNA and RNA, and enhanced nuclease resistance. To understand the structural implications of ^NU and ^NU_m substitutions, we have determined the X-ray crystal structures of DNA:DNA duplexes containing either ^NU or ^NU_m and of DNA:RNA hybrid duplexes containing ^NU_m. The aminohexyl chains are fixed in the major groove through hydrogen bonds between the carbamoyl amino groups and the uracil O4 atoms. The terminal ammonium cations on these chains could interact with the phosphate oxygen anions of the residues in the target strands. These interactions partly account for the increased target binding affinity and nuclease resistance. In contrast to ^NU, ^NU_m decreases DNA binding affinity. This could be explained by the drastic changes in sugar puckering and in the minor groove widths and hydration structures seen in the ^NU_m containing DNA:DNA duplex structure. The conformation of ^NU_m, however, is compatible with the preferred conformation in DNA:RNA hybrid duplexes. Furthermore, the ability of ^NU_m to render the duplexes with altered minor grooves may increase nuclease resistance and elicit RNase H activity.

Synthesis of (2'S)- and (2'R)-2'-deoxy-2'-[(2-methoxyethoxy)amino] pyrimidine nucleosides and oligonucleotides

Syntheses of specified 2'-modified nucleosides were achieved: a) via oximation of the 5',3'-blocked 2'-oxocytidine, followed by reduction, or b) by intramolecular nucleophilic addition of 3'-(2-methoxyethoxy)carbamate to the 2'-position with opening of O(2),2'-anhydrouridine. For the first time, 3'-phosphoroamidites of these 2'-modified nucleosides were successfully incorporated into oligonucleotides by solid-phase synthesis. Incorporation of 2'-modified nucleotides into oligodeoxyribonucleotides had a negative effect on the duplex T(m) values with the DNA or RNA complements. Nevertheless, modified nucleotides have shown good target recognition; the (S)-isomer binds preferably to RNA and the (R)-isomer to DNA. Both modified nucleosides significantly increased nuclease resistance of the oligodeoxyribonucleotides.

Zwitterionic oligonucleotides: a study on binding properties of 2'-O-aminohexyl modifications

2'-O-Aminohexyl side chains provide excellent conditions for zwitterionic interstrand and intrastrand interactions of oligonucleotides. 2'-O-Aminoalkylated phosphoramidites of adenosine and uridine were synthesized and incorporated in increasing number into homo adenosine and homo uridine/thymidine dodecamers, respectively. CD spectra of these dodecamers with complementary sense DNA exhibited a B-DNA type structure. While duplex stability values of all tested oligonucleotides were lower than those of the native oligonucleotides, they were significantly higher than those of 2'-O-heptyl modified oligonucleotides. The destabilization amounted to 0.9, 1.5, and 2.7 degrees C per modification for 2'-O-aminohexyl adenosine, 2'-O-aminohexyl uridine, and 2'-O-heptyl adenosine substitutions. These findings are pointing to a duplex stabilizing effect of the interaction of side chain amino groups with backbone phosphoric acid.

Syntheses of 4'-thioribonucleosides and thermodynamic stability and crystal structure of RNA oligomers with incorporated 4'-thiocytosine

A facile synthetic route for the 4'-thioribonucleoside building block (4'S)N (N = U, C, A and G) with the ribose O4' replaced by sulfur is presented. Conversion of l-lyxose to 1,5-di-O-acetyl-2,3-di-O-benzoyl-4-thio-d-ribofuranose was achieved via an efficient four-step synthesis with high yield. Conversion of the thiosugar into the four ribonucleoside phosphoramidite building blocks was accomplished with additional four steps in each case. Incorporation of 4'-thiocytidines into oligoribonucleotides improved the thermal stability of the corresponding duplexes by approximately 1 degrees C per modification, irrespective of whether the strand contained a single modification or a consecutive stretch of (4'S)C residues. The gain in thermodynamic stability is comparable to that observed with oligoribonucleotides containing 2'-O-methylated residues. To establish potential conformational changes in RNA as a result of the 4'-thio modification and to better understand the origins of the observed stability changes, the crystal structure of the oligonucleotide 5'-r(CC(4'S)CCGGGG) was determined and analyzed using the previously solved structure of the native RNA octamer as a reference. The two 4'-thioriboses adopt conformations that are very similar to the C3'-endo pucker observed for the corresponding sugars in the native duplex. Subtle changes in the local geometry of the modified duplex are mostly due to the larger radius of sulfur compared to oxygen or appear to be lattice-induced. The significantly increased RNA affinity of 4'-thio-modified RNA relative to RNA, and the relatively minor conformational changes caused by the modification render this nucleic acid analog an interesting candidate for in vitro and in vivo applications, including use in RNA interference (RNAi), antisense, ribozyme, decoy and aptamer technologies.