Structural Aspects of Nucleic Acid Analogs and Antisense Oligonucleotides

Hybridization of complementary oligonucleotides is essential to highly valuable research tools in many fields including genetics, molecular biology, and cell biology. For example, an antisense molecule for a particular segment of sense messenger RNA allows gene expression to be selectively turned off, and the polymerase chain reaction requires complementary primers in order to proceed. It is hoped that the antisense approach may lead to therapeutics for treatment of various diseases including cancer. Areas of active research in the antisense field focus on the mechanisms of cellular uptake of antisense molecules and their delivery to specific cell sites, an improved understanding of how these molecules inhibit the production of proteins, as well as the optimization of the chemical stability of antisense molecules and the thermodynamic stability of the duplexes they form with the mRNA targets. The last two issues in particular have prompted chemists to launch an extensive search for oligonucleotide analogs with improved binding properties for hybridization with RNA and higher resistance toward nuclease degradation. During the last years this research has resulted in a flurry of new chemical analogs of DNA and RNA with modifications in the sugar–phosphate backbone as well as in the nucleobase sites. However, to date little effort has been directed toward uncovering the exact origins of the gain or loss in stability when nucleic acid analogs bind to RNA. Although large amounts of thermodynamic data have been collected, the structural perturbations induced by the modifications in hybrid duplexes are only poorly understood. For many modified oligonucleotides the compatibility of protection, coupling, and deprotection chemistry with standard DNA and RNA synthesis protocols makes it now possible to generate modified nucleic acid fragments or mixed oligonucleotides containing modifications at selected sites in quantities suitable for three-dimensional structure investigations. Such studies should reveal the structural origins of the observed changes in affinity and specificity of binding for particular modifications and may guide the development of second-and third-generation antisense molecules. In addition, the availability of a previously unimaginable variety of modified building blocks and the investigation of their structures provides the basis for a deeper understanding of the native DNA and RNA structures. This contribution will summarize the results of X-ray crystallographic structure determinations of modified nucleic acid fragments conducted in our laboratory during the last three years and the insights gained from them.     

Effect of polymethylene and phenylene linking groups on the DNA cleavage specificity of distamycin-linked hydroxamic acid-vanadyl complexes

Two types of distamycin-linked hydroxamic acids (DHA), which contain various lengths of polymethylene chains (PM-DHA) and relatively rigid phenylene ones (Ph-DHA), have been synthesized for the first time. Their DNA cleavage specificities were investigated by an end-labeled fragment cleavage experiment in the presence of vanadyl ion and hydrogen peroxide. The DNA cleavage by the PM-DHA x VO(II) complexes was shown to be very dependent on the length of the chain and the AT sequences. The tetramethylene DHA (1b) complex exhibited highly specific cleavage patterns flanking the 8 and 10 AT sites. Interestingly, the Ph-DHA complexes selectively cleaved the 5' end-labeled strand at the AT sites, but did not cleave the 3' end-labeled strand. The vanadyl complexing moieties and the local sequence conformation of the AT tract are suggested to contribute significantly to the DNA recognition of the PM-DHA x VO(II) complexes.     

DNA oligomers having a diazapyrenium dication (DAP2+); synthesis and DNA cleavage activities.

Aiming at the creation of functionalized antisense DNA oligomers possessing site-selective DNA cleaving activity, viologen and a related compound, diazapyrenium dication (DAP2+), were selected and introduced into oligodeoxyribonucleotides as a functionalized molecule. The conjugation of these functionalized molecules with DNA proceeded smoothly by using standard H-phosphonate chemistry. A part of the DAP(2+)-tethered DNA oligomers was synthesized by a combination of solid support method and liquid phase technique. Viologen-tethered DNA oligomers showed no significant activity toward DNA cleavage in spite of their characteristic ESR spectra. On the other hand, it was observed that the DAP(2+)-tethered DNA oligomers formed more stable duplexes with their complementary strands than the corresponding wild type, and these molecules effectively cleaved the complementary strands at the specific site of 2-3 bases away from the modified phosphoramidate linkage. The effect of position and length of the linker arm on the selectivity in the cleavage reaction was also investigated, and it was found that introduction at the 3'- or 5'-end phosphate site is more favorable, probably due to duplex stabilization.     

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.     

Structure and nuclease resistance of 2',4'-constrained 2'-O-methoxyethyl (cMOE) and 2'-O-ethyl (cEt) modified DNAs

Combining the structural elements of the second generation 2'-O-methoxyethyl (MOE) and locked nucleic acid (LNA) antisense oligonucleotide (AON) modifications yielded the highly nuclease resistant 2',4'-constrained MOE and ethyl bicyclic nucleic acids (cMOE and cEt BNA, respectively). Crystal structures of DNAs with cMOE or cEt BNA residues reveal their conformational preferences. Comparisons with MOE and LNA structures allow insights into their favourable properties for AON applications.     

Surface amplification of invasive cleavage products

A major focus of current efforts in genomics is to elucidate the genetic variations extent within the human population, and to study the effects of these variations upon the human system. The most common type of genetic variations are the single nucleotide polymorphisms (SNPs), which occur every 500-1000 nt in the genome. Large-scale population association studies to study the biological or medical significance of such variations may require the analysis of hundreds of thousands of SNPs on thousands of individuals. We are pursuing development of an approach to large-scale SNP analysis that combines the specificity of invasive cleavage reactions with the parallelism of high density DNA arrays. A surface-immobilized probe oligonucleotide is specifically cleaved in the presence of a complementary target sequence in unamplified human genomic DNA, yielding a 5' phosphate group. High sensitivity detection of this reaction product on the surface is achieved by the use of rolling circle amplification, with an approximate concentration detection limit of 10 fM target DNA. This combination of very specific surface cleavage and highly sensitive surface detection will make possible the rapid and parallel analysis of genetic variations across large populations.     

Synthesis of Novel Nucleic Acid Mimics via the Stereoselective Intermolecular Radical Coupling of 3'-Iodo Nucleosides and Formaldoximes(1)

A highly convergent free radical coupling of alkyl iodides and oximes, mediated by bis(trimethylstannyl) benzopinacolate (8), has been utilized to prepare a series of dimeric nucleosides as mimics of natural nucleic acids. The systematic optimization of the reaction conditions allowed for the single-step conversion of the appropriate iodides and oximes into the 2'-deoxy dimers 9 in moderate to excellent yields. For example, the reaction of 3'-deoxy-3'-iodo-5'-(triphenylmethyl)thymidine (6a) with 3'-O-(tert-butyldiphenylsilyl)-5'-O-(methyleneimino)thymidine (7a) in the presence of 8 in degassed benzene gave an 81% yield of 3'-de(oxyphosphinico)-3'-(methyleneimino)-5'-O-(triphenylmethyl)thymidylyl-(3'-->5')-3'-O-(tert-butyldiphenylsilyl)thymidine (9a). Similarly prepared were dimers containing both pyrimidine (thymine, 5-methylcytosine) and purine (adenine, guanine) bases. The reaction was highly stereoselective, giving only a single dimeric species having the ribo-configuration of the newly introduced C-3'-branched methylene moiety. Also prepared were dimers 16, incorporating 2'-O-methyl ribonucleosides in both halves of the dimer. This required the synthesis of 3'-deoxy-3'-iodo-2'-O-methyl nucleosides 12 as well as 2'-O-methyl-5'-O-methyleneimino nucleosides 15. For example, 5'-O-(tert-butyldiphenylsilyl)-3'-deoxy-3'-iodo-2'-O-methyl-5-methyluridine (12e) was prepared in 80% yield by displacement of the corresponding triflate with Bu(4)NI. Also prepared were the suitably protected 3'-deoxy-3'-iodo adenosine and guanosine derivatives. Compounds 15 were prepared in high yield by a regioselective Mitsunobu reaction to give the corresponding 5'-O-phthalimido nucleosides 13, which were subsequently converted to the requisite oximes 15. In the 2'-O-methyl series, the pinacolate coupling reaction proceeded with efficiency equal to that observed for the 2'-deoxy series 9, but with slightly less stereoselectivity, giving predominantly the C-3'ribo products 16, contaminated with 5-25% of the epimeric material. Mixed base dimers containing both pyrimidine and purine bases at all possible positions, including purine-purine dimers were prepared. The hydroxylamine or methyleneimino (MI) backbone of several representative dimers so prepared was converted via methylation to give the corresponding methylenemethylimino (MMI)-linked compounds, which are novel phosphate surrogates for use in antisense oligonucleotides.     

SPR imaging for label-free multiplexed analyses of DNA N-glycosylase interactions with damaged DNA duplexes

Base excision repair (BER) is the major mechanism for the correction of damaged nucleobases resulting from the alkylation and oxidation of DNA. The first step in the BER pathway consists of excision of the abnormal base by several specific DNA N-glycosylases. A decrease in BER activity was found to be related to an increased risk of carcinogenesis and aging. To investigate BER activities we set up a new device for DNA repair analysis based on surface plasmon resonance imaging (SPRi). Oligonucleotides bearing an abnormal nucleoside, namely 8-oxo-7,8-dihydro-2'-deoxyguanosine and (5'S)-5',8-cyclopurine-2'-deoxynucleoside, were grafted by a pyrrole electro-copolymerization process on a glass prism coated with a gold layer. The latter label-free DNA sensor chip permits the detection of N-glycosylase/AP-lyase activity as well as the binding of repair proteins to DNA damage without cleavage activity. Thus, the Fapy DNA N-glycosylase (Fpg) protein is shown as expected to bind and then cleave its natural substrate, namely 8-oxo-7,8-dihydro-guanine, together with the resulting abasic site. Using the current SPR imaging-based DNA array we observed an original binding activity of Fpg towards the (5'S)-5',8-cyclodAdenosine residue. These results altogether show that SPR imaging may be used to simultaneously and specifically detect recognition and excision of several damaged DNA nucleobases, and constitutes an interesting technique to screen inhibitors of DNA repair proteins.     

Backbone modification promotes peroxidase activity of G-quadruplex-based DNAzyme

In this work we studied how backbone chemical modifications, such as 2'-O-methyl, phosphorothioate, L-form nucleotides and locked nucleic acid, on G-quadruplex based DNAzymes would affect their peroxidase activity. Our results indicate that 2'-O-methyl modification facilitates the formation of a perfectly compacted parallel structure and significantly promotes peroxidase activity of G-quadruplex based DNAzymes.     

RNA-cleaving DNA enzymes with altered regio- or enantioselectivity

In vitro evolution methods were used to obtain DNA enzymes that cleave either a 2',5'-phosphodiester following a D-ribonucleotide or a 3',5'-phosphodiester following an L-ribonucleotide. Both enzymes can operate in an intermolecular reaction format with multiple turnover. The DNA enzyme that cleaves a 2',5'-phosphodiester exhibits a k(cat) of approximately 0.01 min(-1) and catalytic efficiency, k(cat)/K(m), of approximately 10(8) M(-1) min(-1). The enzyme that cleaves an L-ribonucleotide is about 10-fold slower and has a catalytic efficiency of approximately 4 x 10(5) M(-1) min(-1). Both enzymes require a divalent metal cation for their activity and have optimal catalytic rate at pH 7-8 and 35-50 degrees C. In a comparison of each enzyme's activity with either its corresponding substrate that contains an unnatural ribonucleotide or a substrate that instead contains a standard ribonucleotide, the 2',5'-phosphodiester-cleaving DNA enzyme exhibited a regioselectivity of 6000-fold, while the L-ribonucleotide-cleaving DNA enzyme exhibited an enantioselectivity of 40-fold. These molecules demonstrate how in vitro evolution can be used to obtain regio- and enantioselective catalysts that exhibit specificities for nonnatural analogues of biological compounds.     

Polyalkylcyanoacrylate Nanospheres and Nanocapsules for the Delivery of Antisense Oligonucleotides

Abstract

Active ingredients are being aimed at targets implied in various mechanisms such as nuclear enzymes, receptors, membrane receptors or ionic channels. This non‐specific approach leads to adverse effects. From newly acquired knowledge of the genome, one can now plan to treat diseases by the administration of DNA coding for defective proteins. On the other hand, one can also plan to block expression of harmful proteins such as oncogenic proteins by the use of antisense oligonucleotides. These very short nucleic acids sequences are able to specifically form hybrids with an mRNA and to block the translation of the corresponding protein. However, stability issues and an inability to cross membranes and address suitable cellular compartments still limit the use of oligonucleotides as therapeutic agents. In this review, we focus on nanospheres and nanocapsules made of biodegradable polyisobutylcyanoacrylate polymer for the transport and the targeting of antisense oligonucleotides. Nanospheres are particles on the surface of which the oligonucleotides are adsorbed by ion pair formation using a hydrophobic cation. Nanocapsules are a new type of carrier displaying an aqueous content in which oligonucleotides are dissolved. These two systems both allow protection of oligonucleotides against degradation in the presence of pure serum and lead to in vivo inhibition of tumor growth.     

The area-code hypothesis: the immune system provides clues to understanding the genetic and molecular basis of cell recognition during development

Numberous studies of embryogenesis have provided evidence for highly specific cell-surface recognition phenomena. These include both the interactions of neighboring cells and the specific cellular migrations which occur as the developmental program of the embryo progresses. The area-code hypothesis elaborate here is an attempt to provide a framework for understanding cell-recognition phenomena in development. This hypothesis is based on extensive genetic, molecular, and cellular studies of the immune system. These studies suggest that the following events occur during the differentiation of antibody-producing cells. 1) Somatic cell lines of antibody-producing cells undergo a modification of their DNA as they become committed to synthesize a particular type of antibody molecule. This chromosomal modification event is probably a DNA translocation which leads to a somatic rearrangement of certain antibody genes. 2) In each of the specific cell lineages the new arrangement of DNA is inherited by all subsequent generations of cells. 3) The developmental programs which control these genetic alterations may be employed in a programmed and reproducible fashion. This programming of antibody development is suggested because different embryos appear to become committed to the production of identical antibody molecules in the same developmental sequence. 4) Antibody molecules are initially displayed on the cell surface where they serve as highly specifici receptors to trigger the cell to proliferate and differentiate upon interacting with appropriate external molecular signals. 5) Antibody-producing cells display combinations of different molecules on their surfaces which cause each of a very large number of different cells to interact differently with their environment. 6) The genes which code for many of these cell-surface molecules are organized into multigene families. These observations as well as information from other developmental systems have led us to propose the area-code hypothesis. This hypothesis is concerned with the structure, function, and regulation of cell-surface molecules that mediate recognition phenomena during embryogenesis. Area-code molecules are cell-surface molecules which are involved in the specific recognition phenomena during growth and development. These molecules provide cells with distinct cell-surface addresses or phenotypes, and provide the basis for the specificity in cell-cell recognition during cell migrations and cell-cell interactions, as well as serving as receptors for diffusible differentiation signals. The area-code hypothesis has 3 main postulates. i) There is a progressive display of specific combinations of area-code molecules on the surfaces of cells during development. ii) The genetic programs which determine the specific expression of area-code molecules are in part controlled by DNA modifications. These chromosomal modifications are believed to channel cells into specific lineages uith progressively restricted developmental options...     

Metal-free catalysts for the hydrolysis of RNA derived from guanidines, 2-aminopyridines, and 2-aminobenzimidazoles

2-aminopyridine and 2-aminobenzimidazole were chosen as structural analogues to substitute guanidinium groups in receptor molecules designed as phosphoryl transfer catalysts. Shifting the pKa of the guanidinium analogues toward 7 was expected to raise catalytic activities in aqueous buffer. Although the pKa's of both heterocycles are similar (6.2 and 7.0), only 2-aminobenzimidazole led to active RNA cleavers. All cleavage assays were run with fluorescently labeled substrates and a DNA sequencer. RNase contaminations would degrade RNA enantioselectively. In contrast, achiral catalysts such as 9b and 10b necessarily induce identical cleavage patterns in RNA and its mirror image. This principle allowed us to safely rule out contamination effects in this study. The most active catalysts, tris(2-aminobenzimidazoles) 9b and 10b, were shown by fluorescence correlation spectroscopy (FCS) to aggregate with oligonucleotides. However, at very low concentrations the compounds are still active in the nonaggregated state. Conjugates of 10b with antisense oligonucleotides or RNA binding peptides, therefore, will be promising candidates as site specific artificial ribonucleases.     

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

Hydrolytic reactions of 2',3'-O-methyleneadenos-5'-yl 2',5'-di-O-methylurid-3'-yl 5'-O-methylurid-3'(2')-yl phosphate (1a,b) have been followed by RP-HPLC over a wide pH range to evaluate the feasibility of occurrence of phosphate-branched RNA under physiological conditions. At pH <2, where the decomposition of is first order in [H3O+], the P-O5' bond is cleaved 1.5 times as rapidly as the P-O3' bond. Under these conditions, the reaction probably proceeds by an attack of the 2'-OH on the phosphotriester monocation. Over a relatively wide range from pH 2 to 5, the hydrolysis is pH-independent, referring to rapid initial deprotonation of the attacking 2'-OH followed by general acid catalyzed departure of the leaving nucleoside. The P-O5' bond is cleaved 3 times as rapidly as the P-O3' bond. At pH 6, the reaction becomes first order in [HO-], consistent with an attack of the 2'-oxyanion on neutral phosphate. The product distribution is gradually inversed: in 10 mmol L(-1) aqueous sodium hydroxide, cleavage of the P-O3' bond is favored over P-O5' by a factor of 7.3. The results of the present study suggest that the half-life for the cleavage of under physiological conditions is only 100 s. Even at pH 2, where is most stable, the half-life for its cleavage is less than one hour and the isomerization between and is even more rapid than cleavage. The mechanisms of the partial reactions are discussed.     

Dihydrochalcones with radical scavenging properties from the leaves of Syzygium jambos

Chemical investigation of the dichloromethane extract of the leaves of Syzygium jambos furnished three dihydrochalcones, phloretin 4'-O-methyl ether (2',6'-dihydroxy-4'-methoxydihydrochalcone) (1), myrigalone G (2',6'-dihydroxy-4'-methoxy-3'-methyldihydrochalcone) (2), and myrigalone B (2',6'-dihydroxy-4'-methoxy-3,5'-dimethyldihydrochalcone) (3) with radical scavenging properties towards the DPPH radical by spectrophotometric method.     

Conformationally constrained 2'-N,4'-C-ethylene-bridged thymidine (aza-ENA-T): synthesis, structure, physical, and biochemical studies of aza-ENA-T-modified oligonucleotides

The 2'-deoxy-2'-N,4'-C-ethylene-bridged thymidine (aza-ENA-T) has been synthesized using a key cyclization step involving 2'-ara-trifluoromethylsufonyl-4'-cyanomethylene 11 to give a pair of 3',5'-bis-OBn-protected diastereomerically pure aza-ENA-Ts (12a and 12b) with the fused piperidino skeleton in the chair conformation, whereas the pentofuranosyl moiety is locked in the North-type conformation (7 degrees < P < 27 degrees, 44 degrees < phi m < 52 degrees). The origin of the chirality of two diastereomerically pure aza-ENA-Ts was found to be due to the endocyclic chiral 2'-nitrogen, which has axial N-H in 12b and equatorial N-H in 12a. The latter is thermodynamically preferred, while the former is kinetically preferred with Ea = 25.4 kcal mol-1, which is thus far the highest observed inversion barrier at pyramidal N-H in the bicyclic amines. The 5'-O-DMTr-aza-ENA-T-3'-phosphoramidite was employed for solid-phase synthesis to give four different singly modified 15-mer antisense oligonucleotides (AONs). Their AON/RNA duplexes showed a Tm increase of 2.5-4 degrees C per modification, depending upon the modification site in the AON. The relative rates of the RNase H1 cleavage of the aza-ENA-T-modified AON/RNA heteroduplexes were very comparable to that of the native counterpart, but the RNA cleavage sites of the modified AON/RNA were found to be very different. The aza-ENA-T modifications also made the AONs very resistant to 3' degradation (stable over 48 h) in the blood serum compared to the unmodified AON (fully degraded in 4 h). Thus, the aza-ENA-T modification in the AON fulfilled three important antisense criteria, compared to the native: (i) improved RNA target affinity, (ii) comparable RNase H cleavage rate, and (iii) higher blood serum stability.     

Sequence-specific fluorescence detection of DNA by polyamide-thiazole orange conjugates

Fluorescent methods to detect specific double-stranded DNA sequences without the need for denaturation may be useful in the field of genetics. Three hairpin pyrrole-imidazole polyamides 2-4 that target their respective sequences 5'-WGGGWW-3', 5'-WGGCCW-3', and 5'-WGWWCW-3' (W = A or T) were conjugated to thiazole orange dye at the C-termini to examine their fluorescence properties in the presence and absence of match duplex DNA. The conjugates fluoresce weakly in the absence of DNA but showed significant enhancement (>1000-fold) upon the addition of 1 equiv of match DNA and only slight enhancement with the addition of mismatch DNA. The polyamide-dye conjugates bound specific DNA sequences with high affinity (Ka > 10(8) M(-1)) and unwound the DNA duplex through intercalation (unwinding angle, phi, approximately 8 degrees). This new class of polyamides provides a method to specifically detect DNA sequences without denaturation.     

Long-range cooperativity in molecular recognition of RNA by oligodeoxynucleotides with multiple C5-(1-propynyl) pyrimidines.

A heptamer composed of C5-(1-propynyl) pyrimidines (Y(p)'s) is a potent and specific antisense agent against the mRNA of SV40 large T antigen (Wagner, R. W.; Matteucci, M. D.; Grant, D.; Huang, T.; Froehler, B. C. Nat. Biotechnol. 1996, 14, 840-844). To characterize the role of the propynyl groups in molecular recognition, thermodynamic increments associated with substitutions in DNA:RNA duplexes, such as 5'-dCCUCCUU-3':3'-rGAGGAGGAAAU-5', have been measured by UV melting experiments. For nucleotides tested, an unpaired dangling end stabilizes unmodified and propynylated duplexes similarly, except that addition of a 5' unpaired rA is 1.4 kcal/mol more stabilizing on the propynylated, PODN:RNA, duplex than on the DNA:RNA duplex. Free energy increments for addition of single propynyl groups range from 0 to -4.0 kcal/mol, depending on the final number and locations of substitutions. A preliminary model for predicting the stabilities of Y(p)-containing hybrid duplexes is presented. Eliminating one amino group, and therefore a hydrogen bond, by substituting inosine (I) for guanosine (G), to give 5'-dC(p)C(p)U(p)C(p)C(p)U(p)U(p)-3':3'-rGAGIAGGAAAU-5', destabilizes the duplex by 3.9 kcal/mol, compared to 1.7 kcal/mol for the same change within the unpropynylated duplex. This 2.2 kcal/mol difference is eliminated by removing a single propynyl group three base pairs away. CD spectra suggest that single propynyl deletions within the PODN:RNA duplex have position-dependent effects on helix geometry. The results suggest long-range cooperativity between propynyl groups and provide insights for rationally programming oligonucleotides with enhanced binding and specificity. This can be exploited in developing technologies that are dependent upon nucleic acid-based molecular recognition.