The synthesis of previously unknown derivatives of boranephosphonate that contain amine substitutions at boron and the incorporation of these derivatives into the backbone of DNA oligonucleotides is described. These derivatives result from iodine-mediated replacement of one BH3 hydride of a boranephosphonate linkage by pyridine, various substituted pyridines, other aromatic amines, and certain unsaturated amines. Oligonucleotides containing these backbone modifications show enhanced uptake, relative to unmodified DNA, in mammalian cells. The redox behavior of the boranephosphonate and pyridinium boranephosphonate conjugated linkages has also been studied.

Phosphorodiamidate morpholinos (PMOs) and PMO–DNA chimeras have been prepared on DNA synthesizers using phosphoramidite chemistry. This was possible by first generating boranephosphoroamidate morpholino internucleotide linkages followed by oxidative substitution with four different amines: N,N-dimethylamine, N-methylamine, ammonia, and morpholine. When compared to a natural DNA duplex, the amino modified PMO was found to have a higher melting temperature with either complementary DNA or RNA, whereas the remaining PMO analogues having morpholino, dimethylamino, or N-methylamino phosphorodiamidate linkages had melting temperatures that were either comparable or reduced. Additionally the N,N-dimethylamino PMO–DNA chimeras were found to stimulate RNaseH1 activity. Treatment of HeLa cells with fluorescently labeled PMO chimeras demonstrated that these analogues were efficiently taken up by cells in the presence of a lipid transfection reagent. Because of the simplistic synthesis procedures, various PMO analogues are now readily available and should therefore open new pathways for research into the antisense, diagnostic, and nanotechnology oligonucleotide fields.

The introduction of modifications into oligonucleotides is important for a large number of applications in the nucleic acids field. However, the method of solid-phase DNA synthesis presents significant challenges for incorporating many useful modifications that are unstable to the conditions for preparing synthetic DNA. Here we report that boranephosphonate diesters undergo facile nucleophilic substitution in a stereospecific manner upon activation by iodine. We have subsequently used this reactivity to post-synthetically introduce modifications including azides and fluorophores into DNA by first synthesizing boranephosphonate-linked 2′-deoxyoligonucleotides and then treating these oligomers with iodine and various nucleophiles. In addition, we show that this reaction is an attractive method for preparing stereodefined phosphorus-modified oligonucleotides. We have also examined the mechanism of this reaction and show that it proceeds via an iodophosphate intermediate. Beyond nucleic acids synthesis, due to the ubiquity of phosphate derivatives in natural compounds and therapeutics, this stereospecific reaction has many potential applications in organophosphorus chemistry.

We investigate the efficiency of incorporation of boranephosphonate-modified nucleotides by phi29 DNA polymerase and present a simple method for forming large defined silver nanostructures by rolling circle amplification (RCA) using boranephosphonate internucleotide linkages. RCA is a linear DNA amplification technique that can use specifically circularized DNA probes for detection of target nucleic acids and proteins. The resulting product is a collapsed single-stranded DNA molecule with tandem repeats of the DNA probe. By substituting each of the natural nucleotides with the corresponding 5′-(α-P-borano)deoxynucleosidetriphosphate, only a small reduction in amplification rate is observed. Also, by substituting all four natural nucleotides, it is possible to enzymatically synthesize a micrometer-sized, single-stranded DNA molecule with only boranephosphonate internucleotide linkages. Well-defined silver particles are then readily formed along the rolling circle product.

Analogues of oligonucleotides and mononucleotides with hydrophobic and/or cationic phophotriester functionalities often generate an improvement in target affinity and cellular uptake. Here we report the synthesis of phosphotriester oligodeoxyribonucleotides (ODNs) that are stable to the conditions used for their preparation. The method has been demonstrated by introducing phosphoramidite synthons where N-benzyloxycarbonyl (Z) protected amino alcohols replace the cyanoethyl group. After synthesis these ODNs were found to be stable to the condition required to remove base labile protecting groups and the ODNs from the solid support. Moreover the use of 1-(4,4-dimethyl-2, 6-dioxocyclohex-1-ylidene) ethyl (Dde) in place of Z protection on the amino alcohol has allowed us to introduce cationic aminoethyl phosphotriester modifications into ODNs. Melting temperatures of duplexes containing cationic or hydrophobic Z modified ODNs indicate that the backbone-phosphotriester modifications minimally affect duplex stability. Nuclease stability assays demonstrate that these phosphotriesters are resistant toward 5′- and 3′-exonucleases. Fluorescently labeled 23-mer ODNs modified with four cationic or hydrophobic Z phosphotriester linkages show efficient cellular uptake during passive transfection in HeLa and Jurkat cells.

Spatially selective deposition of metal onto complex DNA assemblies is a promising approach for the preparation of metallic nanostructures with features that are smaller than what can be produced by top-down lithographic techniques. We have recently reported the ability of 2′-deoxyoligonucleotides containing boranephosphonate linkages (bpDNA) to reduce AuCl4–, Ag+, and PtCl42– ions to the corresponding nanoparticles. Here we demonstrate incorporation of bpDNA oligomers into a two-dimensional DNA array comprised of tiles containing double crossover junctions. We further demonstrate the site-specific deposition of metallic silver onto this DNA structure which generates well-defined and preprogrammed arrays of silver nanoparticles. With this approach the size of the metallic features that can be produced is limited only by the underlying DNA template. These advances were enabled due to a new method for synthesizing bpDNA that uses a silyl protecting group on the DNA nucleobases during the solid-phase 2′-deoxyoligonucleotide synthesis.

Major hurdles associated with DNA-based biological applications include, among others, targeted cell delivery, undesirable nonspecific effects, toxicity associated with various analogues or the reagents used to deliver oligonucleotides to cells, and stability toward intracellular enzymes. Although a plethora of diverse analogues have been investigated, a versatile methodology that can systematically address these challenges has not been developed. In this contribution, we present a new, Clickable, and versatile chemistry that can be used to rapidly introduce diverse functionality for studying these various problems. As a demonstration of the approach, we synthesized the core analogue, which is useful for introducing additional functionality, the triazolylphosphonate, and present preliminary data on its biological properties. We have developed a new phosphoramidite synthon—the alkynyl phosphinoamidite, which is compatible with conventional solid-phase oligonucleotide synthesis. Postsynthesis, the alkynylphosphonate can be functionalized via “Click” chemistry to generate the 1,2,3-triazolyl or substituted 1,2,3-triazolyl phosphonate-2′-deoxyribonucleotide internucleotide linkage. This manuscript describes the automated, solid-phase synthesis of mixed backbone oligodeoxyribonucleotides (ODNs) having 1,2,3-triazolylphosphonate (TP) as well as phosphate or thiophosphate internucleotide linkages and also 2′-OMe ribonucleotides and locked nucleic acids (LNAs) at selected sites. Nuclease stability assays demonstrate that the TP linkage is highly resistant toward 5′- and 3′-exonucleases, whereas melting studies indicate a slight destabilization when a TP-modified ODN is hybridized to its complementary RNA. A fluorescently labeled 16-mer ODN modified with two TP linkages shows efficient cellular uptake during passive transfection. Of particular interest, the subcellular distribution of TP-modified ODNs is highly dependent on cell type; a significant nuclear uptake is observed in HeLa cells, whereas diffuse cytoplasmic fluorescence is found in the WM-239A cell line. Cytoplasmic distribution is also present in human neuroblastoma cells (SK-N-F1), but Jurkat cells show both diffuse and punctate cytoplasmic uptake. Our results demonstrate that triazolylphosphonate ODNs are versatile additions to the oligonucleotide chemist’s toolbox relative to designing new biological research reagents.

Chimeric 2′-O-methyl oligoribonucleotides (2′-OMe ORNs) containing internucleotide linkages which were modified with phosphonoacetate (PACE) or thiophosphonoacetate (thioPACE) were prepared by solid-phase synthesis. The modified 2′-OMe ORNs contained a central phosphate or phosphorothioate sequence with up to 4 PACE or thioPACE modifications, respectively, at either end of the ORN in a “gapmer” motif. Both PACE and thioPACE 2′-OMe ORNs formed stable duplexes with complementary RNA. The majority of these duplexes had higher thermal melting temperatures than an unmodified RNA:RNA duplex. The modified 2′-OMe ORNs were effective passenger strands with complementary, unmodified siRNAs, for inducing siRNA activity in a dual luciferase assay in the presence of a lipid transfecting agent. As single strands, thioPACE 2′-OMe ORNs were efficiently taken up by HeLa cells in the absence of a lipid transfecting agent. Furthermore, thioPACE modifications greatly improved the potency of a 2′-OMe phosphorothioate ORN as an inhibitor of microRNA-122 in Huh7 cells, without lipid transfection.

Oligodeoxyribonucleotides bearing boranephosphonate linkages (bpDNA) were shown to reduce a number of metal ions and form nanoparticles through a novel reaction pathway that leads to phosphate diesters or phosphate triesters in water or alcohols respectively. The synthetic utility of this reaction was further demonstrated through the synthesis of oligodeoxyribonucleotides containing phosphate triester linkages. This new reactivity also makes bpDNA promising for use in construction of DNA templated metallic nanostructures.

The major hurdle associated with utilizing oligodeoxyribonucleotides for therapeutic purposes is their poor delivery into cells coupled with high nuclease susceptibility. In an attempt to combine the nonionic nature and high nuclease stability of the P–C bond of methylphosphonates with the high membrane permeability, low toxicity, and improved gene silencing ability of borane phosphonates, we have focused our research on the relatively unexplored methylborane phosphine (Me–P–BH3) modification. This Article describes the automated solid-phase synthesis of mixed-backbone oligodeoxynucleotides (ODNs) consisting of methylborane phosphine and phosphate or thiophosphate linkages (16-mers). Nuclease stability assays show that methylborane phosphine ODNs are highly resistant to 5′ and 3′ exonucleases. When hybridized to a complementary strand, the ODN:RNA duplex was more stable than its corresponding ODN:DNA duplex. The binding affinity of ODN:RNA duplex increased at lower salt concentration and approached that of a native DNA:RNA duplex under conditions close to physiological saline, indicating that the Me–P–BH3 linkage is positively charged. Cellular uptake measurements indicate that these ODNs are efficiently taken up by cells even when the strand is 13% modified. Treatment of HeLa cells and WM-239A cells with fluorescently labeled ODNs shows significant cytoplasmic fluorescence when viewed under a microscope. Our results suggest that methylborane phosphine ODNs may prove very valuable as potential candidates in antisense research and RNAi.

Oligodeoxyribonucleotides bearing boranephosphonate linkages (bpDNA) were shown to reduce a number of metal ions and form nanoparticles through a novel reaction pathway that leads to phosphate diesters or phosphate triesters in water or alcohols respectively. The synthetic utility of this reaction was further demonstrated through the synthesis of oligodeoxyribonucleotides containing phosphate triester linkages. This new reactivity also makes bpDNA promising for use in construction of DNA templated metallic nanostructures.

Chimeric 2′-O-methyl oligoribonucleotides (2′-OMe ORNs) containing internucleotide linkages which were modified with phosphonoacetate (PACE) or thiophosphonoacetate (thioPACE) were prepared by solid-phase synthesis. The modified 2′-OMe ORNs contained a central phosphate or phosphorothioate sequence with up to 4 PACE or thioPACE modifications, respectively, at either end of the ORN in a “gapmer” motif. Both PACE and thioPACE 2′-OMe ORNs formed stable duplexes with complementary RNA. The majority of these duplexes had higher thermal melting temperatures than an unmodified RNA:RNA duplex. The modified 2′-OMe ORNs were effective passenger strands with complementary, unmodified siRNAs, for inducing siRNA activity in a dual luciferase assay in the presence of a lipid transfecting agent. As single strands, thioPACE 2′-OMe ORNs were efficiently taken up by HeLa cells in the absence of a lipid transfecting agent. Furthermore, thioPACE modifications greatly improved the potency of a 2′-OMe phosphorothioate ORN as an inhibitor of microRNA-122 in Huh7 cells, without lipid transfection.