DNA Three-Way Junctions Stabilized by Hydrophobic Interactions for Creation of Functional Nanostructures.

The construction of nanomaterials from oligonucleotides by modular assembly invariably requires the use of branched nucleic acid architectures such as three- and four-way junctions (3WJ and 4WJ). We describe the stabilization of DNA 3WJ by using non-nucleotide lipophilic spacers to create a hydrophobic pocket within the junction space. Stabilization of nucleic acid junctions is of particular importance when constructing nanostructures in the "ultra-nano" size range (<20 nm) with shorter double-stranded regions. UV thermal melting studies show that lipophilic spacers strategically placed within the junction space significantly increased thermal stability. For a 3WJ with eight base pair arms, thermal stability was increased from 30.5 °C for the unmodified junction to a maximum stability of 55.0 °C. The stability of the junction can be modulated within this temperature range by using the appropriate combinations of spacers.

Evaluation of end-capped DNA modules for pRNA capture and functionalization.

The ability of packaging RNA (pRNA) from the phi29 DNA packaging motor to form nanoassemblies and nanostructures has been exploited for the development of the nascent field of RNA nanotechnology and subsequent applications in nanomedicine. For applications in nanomedicine, it is necessary to modify the pRNA structure for the conjugation of active molecules. We have investigated end-capped double-stranded DNA segments as reversible capture reagents for pRNA. These capture agents can be designed to allow the conjugation of any desired molecule for pRNA functionalization. The results of model studies presented in this report show that 5- to 7-nucleotide overhangs on a target RNA can provide efficient handles for the high-affinity association to capped double-stranded DNA.

Optimized method for the synthesis and purification of adenosine--folic acid conjugates for use as transcription initiators in the preparation of modified RNA.

We present an optimized synthetic strategy for the attachment of molecules to 5'-adenosine monophosphate (AMP), which can then be used to label the 5'-end of RNA by T7 RNA polymerase mediated in vitro transcription. Through the use of a boronate affinity gel, we have developed an efficient route to the preparation of folate conjugated AMP with high yields and purity. Affi-Gel boronate is an affinity resin that selectively binds nucleoside and nucleoside derivatives at pH>7.5 and releases them at pH<6.5. This resin is used to efficiently bind and purify ribonucleotides such as AMP. This allows for the addition of a large excess of reactants and reagents in order to drive the reaction to completion and then allow easy purification without HPLC. The synthesis can be successfully scaled up to produce large quantities of AMP conjugates.

Properties of double-stranded oligonucleotides modified with lipophilic substituents.

We have synthesized a series of short, self-complementary oligonucleotide sequences modified at their 5'- and/or 3'- termini with a lipophilic dodecane (C12); these systems serve as models to assess the biophysical properties of double-stranded DNA (dsDNA) equipped with potentially stabilizing lipophilic substituents. Addition of C12 to the 5'-termini of self-complementary 10 nucleotide sequences increased their duplex melting temperatures (T(m)) by approximately 4-8 degrees C over their corresponding unmodified sequences. C12 functionalities added to both the 3'- and 5'-termini increased T(m) values by approximately 10-12 degrees C. The observed increases in T(m) correlated with greater duplex stabilities as determined by the free energy values (DeltaG) derived from T(m) plots. There is a greater degree of stabilization when C12 is positioned with a C.G base pair at the termini, and the stabilizing effect of lipophilic groups far exceeds the effect seen in adding an additional base pair to both ends of DNA. Stable, short dsDNA sequences are of potential interest in the development of transcription factor decoy oligonucleotides as possible therapeutic agents and/or biological tools. These results suggest that the stability of short dsDNA sequences are improved by lipophilic substituents and can be used as the basis for the design of dsDNAs with improved biological stabilities and function under physiological conditions.

Synthesis and evaluation of new spacers for use as dsDNA end-caps.

A series of aliphatic and aromatic spacer molecules designed to cap the ends of DNA duplexes have been synthesized. The spacers were converted into dimethoxytrityl-protected phosphoramidites as synthons for oligonucleotides synthesis. The effect of the spacers on the stability of short DNA duplexes was assessed by melting temperature studies. End-caps containing amide groups were found to be less stabilizing than the hexaethylene glycol spacer. End-caps containing either a terthiophene or a naphthalene tetracarboxylic acid diimide were found to be significantly more stabilizing. The former showed a preference for stacking above an A*T base pair. Spacers containing only methylene (-CH(2)-) and amide (-CONH-) groups interact weakly with DNA and consequently may be optimal for applications that require minimal influence on DNA structure but require a way to hold the ends of double-stranded DNA together.