Design, biochemical, biophysical and biological properties of cooperative antisense oligonucleotides.

Short oligonucleotides that can bind to adjacent sites on target mRNA sequences are designed and evaluated for their binding affinity and biological activity. Sequence-specific binding of short tandem oligonucleotides is compared with a full-length single oligonucleotide (21mer) that binds to the same target sequence. Two short oligonucleotides that bind without a base separation between their binding sites on the target bind cooperatively, while oligonucleotides that have a one or two base separation between the binding oligonucleotides do not. The binding affinity of the tandem oligonucleotides is improved by extending the ends of the two oligonucleotides with complementary sequences. These extended sequences form a duplex stem when both oligonucleotides bind to the target, resulting in a stable ternary complex. RNase H studies reveal that the cooperative oligonucleotides bind to the target RNA with sequence specificity. A short oligonucleotide (9mer) with one or two mismatches does not bind at the intended site, while longer oligonucleotides (21mers) with one or two mismatches still bind to the same site, as does a perfectly matched 21mer, and evoke RNase H activity. HIV-1 inhibition studies reveal an increase in activity of the cooperative oligonucleotide combinations as the length of the dimerization domain increases.     

Application of Equilibrium Models of Solution Hybridization to Microarray Design and Analysis

Background

The probe percent bound value, calculated using multi-state equilibrium models of solution hybridization, is shown to be useful in understanding the hybridization behavior of microarray probes having 50 nucleotides, with and without mismatches. These longer oligonucleotides are in widespread use on microarrays, but there are few controlled studies of their interactions with mismatched targets compared to 25-mer based platforms.

Principal Findings

50-mer oligonucleotides with centrally placed single, double and triple mismatches were spotted on an array. Over a range of target concentrations it was possible to discriminate binding to perfect matches and mismatches, and the type of mismatch could be predicted accurately in the concentration midrange (100 pM to 200 pM) using solution hybridization modeling methods. These results have implications for microarray design, optimization and analysis methods.

Conclusions

Our results highlight the importance of incorporating biophysical factors in both the design and the analysis of microarrays. Use of the probe “percent bound” value predicted by equilibrium models of hybridization is confirmed to be important for predicting and interpreting the behavior of long oligonucleotide arrays, as has been shown for short oligonucleotide arrays.     

Chemical interrogation of mismatches in DNA-DNA and DNA-RNA duplexes under nonstringent conditions by selective 2'-amine acylation

2'-Amine-substituted nucleotides in hybridized duplexes can be chemically tagged in an acylation reaction that is faster for mismatched or flexible nucleotides than for residues constrained by base pairing. Here we explore mismatch and hybridization detection using probe oligodeoxynucleotides containing single 2'-aminocytidine or -uridine nucleotides annealed to DNA or RNA targets under nonstringent conditions, below T(m). Consistent with a mechanism in which 2'-amine acylation is gated by local nucleotide flexibility, we find that efficient acylation is correlated with formation of weaker or fewer hydrogen bonds in base pair mismatches. Using 2'-aminocytidine-containing probes annealed to both DNA and RNA targets, mismatches are reliably detected as rapid selective acylation of the 2'-amine group in two sequence contexts. For probe oligonucleotides containing 2'-aminouridine residues, good discrimination between U-A base pairs and U-G mismatches could be obtained for DNA-DNA but not for DNA-RNA duplexes upon the introduction of a single 2'-O-Me group 5' to the 2'-amino nucleotide. The 2'-O-Me group introduces a structural perturbation, presumably to a more A-form-like structure, that exaggerates local flexibility at mismatches in DNA strands. Thus, 2'-amine acylation can be used to interrogate all possible mismatches in DNA-DNA duplexes and mismatches involving 2'-amine-substituted cytidine nucleotides in DNA-RNA heteroduplexes. Applications of this chemistry include detecting and chemically proofreading single nucleotide polymorphisms in both DNA and RNA targets and quantifying absolute amounts of RNA.     

Hybridization of glass-tethered oligonucleotide probes to target strands preannealed with labeled auxiliary oligonucleotides

In this article we introduce a strategy of preanncaling labeled auxiliary oligonucleotides to single-stranded target DNA, prior to hybridization of the DNA target to oligonucleotide arrays (genosensors) formed on glass slides for the purpose of mutation analysis. Human genomic DNA samples from normal individuals and cystic fibrosis (CF) patients (including homozygous δF508 and heterozygous δF508/wild type (wt) in the region examined) were used. A PCR fragment of length 138 bp (wt) or 135 bp (mutant) was produced from exon l0 in the cystic fibrosis transmembrane conductance regulator (CFTR) gene, using a new pair of polymerase chain reaction (PCR) primers. This fragment contains four of the most frequent mutation sites causing the disease (Q493X, δI507, δF508, and V520F). Each of these mutations was tested using a pair of nonamer (9-mer) probes covalently attached to glass slides, representing the normal (wt) and the mutant allcles. Single-stranded target DNA was isolated from the PCR fragment using one PCR primer labeled with biotin and a streptavidin minicolumn to capture the biotin-labeled strand. Prior to hybridization to the 9-mer array on a glass slide, the unlabeled target strand was preannealed with one, three, or four auxiliary oligonucleotides, at least one being labeled with³²P. As observed previously in several laboratories, the discrimination between normal (wt) and mutant alleles at each site using oligonucleotide array hybridization ranged from very good to poor, depending on the number and location of mismatches between probe and target. Terminal mismatches along the probe were difficult to discriminate, internal mismatches were more easily discriminated, and multiple mismatches were very well discriminated. An exceptionally intense hybridization signal was obtained with a 9-mer probe that hybridized contiguously (in tandem) with one auxiliary oligonucleotide preannealed to the target DNA. The increased stability is apparently caused by strong base slacking interactions between the “capture probe” and the auxiliary oligonucleotide. The presence of the δF508 mutation was delected with this system, including discrimination between homozygous and heterozygous conditions. Base mismatch discrimination using the arrayed 9-mcr probes was improved by increasing the temperature of hybridization from 15 to 25‡C. Auxiliary oligonucleotides, preannealed to the single-stranded template, may serve several purposes to enable a more robust genosensor-based DNA sequence analysis:

Mismatch formation in solution and on DNA microarrays: how modified nucleosides can overcome shortcomings of imperfect hybridization caused by oligonucleotide composition and base pairing

The DNA microarray technology is a well-established and widely used technology although it has several drawbacks. The accurate molecular recognition of the canonical nucleobases of probe and target is the basis for reliable results obtained from microarray hybridization experiments. However, the great flexibility of base pairs within the DNA molecule allows the formation of various secondary structures incorporating Watson-Crick base pairs as well as non-canonical base pair motifs, thus becoming a source of inaccuracy and inconsistence. The first part of this report provides an overview of unusual base pair motifs formed during molecular DNA interaction in solution highlighting selected secondary structures employing non-Watson-Crick base pairs. The same mispairing phenomena obtained in solution are expected to occur for immobilized probe molecules as well as for target oligonucleotides employed in microarray hybridization experiments the effect of base pairing and oligonucleotide composition on hybridization is considered. The incorporation of nucleoside derivatives as close shape mimics of the four canonical nucleosides into the probe and target oligonucleotides is discussed as a chemical tool to resolve unwanted mispairing. The second part focuses non-Watson-Crick base pairing during hybridization performed on microarrays. This is exemplified for the unusual stable dG.dA base pair.     

A simple method for the detection of neurologic disorders associated with CAG repeat expansion using PCR-microtiter plate hybridization

A new screening method was developed for the detection of CAG expanded alleles in patients with hereditary ataxia using polymerase chain reaction-based microtiter plate hybridization (PCR-MPH). The system can be applied to detect pathologic alleles by hybridization with the immobilized (CAG)48 repeat probe derived from the unrelated gene 'ERDA1' except for the CAG repeats. We examined 10 individuals with SCA3, 10 with Huntington disease and 30 normal controls (31 controls for SCA3) using this method. The results showed that a clear discrimination was possible in all cases. We suggest that this system be made available for mass screening of patients with hereditary ataxia disorders. This report is the first to demonstrate that a PCR-MPH system can be successfully applied to DNA size differentiation in addition to base pair mismatches. Also, our design of the probe is unique in that the probe motif stem from the unrelated gene sequence and not from the synthetic oligonucleotides.     

Small RNAs with imperfect match to endogenous mRNA repress translation. Implications for off-target activity of small inhibitory RNA in mammalian cells

A 21-base pair RNA duplex that perfectly matches an endogenous target mRNA selectively degrades the mRNA and suppresses gene expression in mammalian tissue culture cells. A single base mismatch with the target is believed to protect the mRNA from degradation, making this type of interference highly specific to the targeted gene. A short RNA with mismatches to a target sequence present in multiple copies in the 3'-untranslated region of an exogenously expressed gene can, however, silence it by translational repression. Here we report that a mismatched RNA, targeted to a single site in the coding sequence of an endogenous gene, can efficiently silence gene expression by repressing translation. The antisense strand of such a mismatched RNA requires a 5'-phosphate but not a 3'-hydroxyl group. G.U wobble base pairing is tolerated as a match for both RNA degradation and translation repression. Together, these findings suggest that a small inhibitory RNA duplex can suppress expression of off-target cellular proteins by RNA degradation or translation repression. Proper design of experimental small inhibitory RNAs or a search for targets of endogenous micro-RNAs must therefore take into account that these short RNAs can affect expression of cellular genes with as many as 3-4 base mismatches and additional G.U mismatches.     

Modeling formamide denaturation of probe-target hybrids for improved microarray probe design in microbial diagnostics

Application of high-density microarrays to the diagnostic analysis of microbial communities is challenged by the optimization of oligonucleotide probe sensitivity and specificity, as it is generally unfeasible to experimentally test thousands of probes. This study investigated the adjustment of hybridization stringency using formamide with the idea that sensitivity and specificity can be optimized during probe design if the hybridization efficiency of oligonucleotides with target and non-target molecules can be predicted as a function of formamide concentration. Sigmoidal denaturation profiles were obtained using fluorescently labeled and fragmented 16S rRNA gene amplicon of Escherichia coli as the target with increasing concentrations of formamide in the hybridization buffer. A linear free energy model (LFEM) was developed and microarray-specific nearest neighbor rules were derived. The model simulated formamide melting with a denaturant m-value that increased hybridization free energy (ΔG°) by 0.173 kcal/mol per percent of formamide added (v/v). Using the LFEM and specific probe sets, free energy rules were systematically established to predict the stability of single and double mismatches, including bulged and tandem mismatches. The absolute error in predicting the position of experimental denaturation profiles was less than 5% formamide for more than 90 percent of probes, enabling a practical level of accuracy in probe design. The potential of the modeling approach for probe design and optimization is demonstrated using a dataset including the 16S rRNA gene of Rhodobacter sphaeroides as an additional target molecule. The LFEM and thermodynamic databases were incorporated into a computational tool (ProbeMelt) that is freely available at http://DECIPHER.cee.wisc.edu.     

High sequence fidelity in a non-enzymatic DNA autoligation reaction.

The success of oligonucleotide ligation assays in probing specific sequences of DNA arises in large part from high enzymatic selectivity against base mismatches at the ligation junction. We describe here a study of the effect of mismatches on a new non-enzymatic, reagent-free method for ligation of oligonucleotides. In this approach, two oligonucleotides bound at adjacent sites on a complementary strand undergo autoligation by displacement of a 5'-end iodide with a 3'-phosphorothioate group. The data show that this ligation proceeds somewhat more slowly than ligation by T4 ligase, but with substantial discrimination against single base mismatches both at either side of the junction and a few nucleotides away within one of the oligonucleotide binding sites. Selectivities of >100-fold against a single mismatch are observed in the latter case. Experiments at varied concentrations and temperatures are carried out both with the autoligation of two adjacent linear oligonucleotides and with intramolecular autoligation to yield circular 'padlock' DNAs. Application of optimized conditions to discrim-ination of an H- ras codon 12 point mutation is demonstrated with a single-stranded short DNA target.     

Genetic evidence that Tn10 transposes by a nonreplicative mechanism

We present genetic evidence that the tetracycline resistance element Tn10 transposes by a nonreplicative mechanism. Heteroduplex Tn10 elements containing three single base pair mismatches were constructed on lambda phage genomes and allowed to transpose from lambda into the bacterial chromosome. Analysis of TetR colonies resulting from such transpositions suggests that information from both strands of the transposing Tn10 element is transmitted faithfully to its transposition product. The simplest interpretation of these results is that the transposing element is excised from the donor molecule and inserted into the target molecule without being replicated. A mismatch 70 base pairs from one end of the transposon is preserved, suggesting that there is little or no replication, even at the termini of the element, during transposition in vivo.     

Splice-switching efficiency and specificity for oligonucleotides with locked nucleic acid monomers

The use of antisense oligonucleotides to modulate splicing patterns has gained increasing attention as a therapeutic platform and, hence, the mechanisms of splice-switching oligonucleotides are of interest. Cells expressing luciferase pre-mRNA interrupted by an aberrantly spliced beta-globin intron, HeLa pLuc705, were used to monitor the splice-switching activity of modified oligonucleotides by detection of the expression of functional luciferase. It was observed that phosphorothioate 2'-O-methyl RNA oligonucleotides containing locked nucleic acid monomers provide outstanding splice-switching activity. However, similar oligonucleotides with several mismatches do not impede splice-switching activity which indicates a risk for off-target effects. The splice-switching activity is abolished when mismatches are introduced at several positions with locked nucleic acid monomers suggesting that it is the locked nucleic acid monomers that give rise to low mismatch discrimination to target pre-mRNA. The results highlight the importance of rational sequence design to allow for high efficiency with simultaneous high mismatch discrimination for splice-switching oligonucleotides and suggest that splice-switching activity is tunable by utilizing locked nucleic acid monomers.     

Isolation of the human insulin-like growth factor I gene using a single synthetic DNA probe.

A single synthetic oligonucleotide was employed as hybridization probe to detect and enable isolation of the human insulin-like growth factor I (IGF-I) gene from a human genomic DNA library. The synthetic oligonucleotide probe coded for the B-chain of IGF-I and was designed for expression in Escherichia coli. Despite numerous interspersed mismatches, the synthetic probe hybridized specifically with seven recombinant lambda phage containing almost the entire B-chain region of the human IGF-I gene. The usefulness of this approach was further demonstrated by the detection of lambda phage containing human preproinsulin, using A and B chain synthetic oligonucleotides, 90 and 63 nucleotides in length, as hybridization probes. The nucleotide sequence of the human IGF-I exon suggests that IGF-I is synthesized as a larger precursor molecule.     

Ectopic gene conversions increase the G + C content of duplicated yeast and Arabidopsis genes

Allelic recombination has previously been shown to increase the GC-content of the sequences of a wide variety of eukaryotic species. Ectopic recombination between clustered tandemly repeated genes has also been shown to increase their GC-content. Here we show that gene conversions between the dispersed genes found in the duplicated regions of the yeast and Arabidopsis genomes also increase their GC-content when these genes are more than 88% similar.     

A high-throughput assay for the comprehensive profiling of DNA ligase fidelity

DNA ligases have broad application in molecular biology, from traditional cloning methods to modern synthetic biology and molecular diagnostics protocols. Ligation-based detection of polynucleotide sequences can be achieved by the ligation of probe oligonucleotides when annealed to a complementary target sequence. In order to achieve a high sensitivity and low background, the ligase must efficiently join correctly base-paired substrates, while discriminating against the ligation of substrates containing even one mismatched base pair. In the current study, we report the use of capillary electrophoresis to rapidly generate mismatch fidelity profiles that interrogate all 256 possible base-pair combinations at a ligation junction in a single experiment. Rapid screening of ligase fidelity in a 96-well plate format has allowed the study of ligase fidelity in unprecedented depth. As an example of this new method, herein we report the ligation fidelity of Thermus thermophilus DNA ligase at a range of temperatures, buffer pH and monovalent cation strength. This screen allows the selection of reaction conditions that maximize fidelity without sacrificing activity, while generating a profile of specific mismatches that ligate detectably under each set of conditions.     

The effect of base mismatches in the substrate recognition helices of hammerhead ribozymes on binding and catalysis.

The ability of the hammerhead ribozyme to distinguish between matched and mismatched substrates was evaluated using two kinetically defined ribozymes that differed in the length and sequence of the substrate recognition helices. A mismatch in the innermost base pair of helix I affected k2, the chemical cleavage step, while more distal mismatches had no such effect. In contrast, mismatches in any of the four innermost base pairs of helix III affected k2. Chase experiments indicated that mismatches also increased the rate of substrate dissociation by at least 20-100-fold, as expected from the stabilities of RNA helices.     

Synthetic deoxyoligonucleotides as general probes for chloroplast transfer RNA genes

The utility of chemically synthesized deoxyoligonucleotides as hybridization probes for the detection of tRNA genes has been examined. Chloroplast tRNA genes were chosen for this study. Deoxyoligonucleotides complementary to highly conserved regions of chloroplast tRNA genes of both higher plants and Euglena gracilis were chemically synthesized. These synthetic probes have been used to detect tRNA genes by Southern hybridizations to restriction fragments of chloroplast DNAs. This new method of tRNA gene mapping and the oligonucleotides synthesized may be of general application to many chloroplast genomes. This is illustrated by the detection of known and unknown tRNA genes of Euglena gracilis and spinach, and unknown tRNA genes of maize and cucumber chloroplast DNAs. The precise locus and polarity of the Euglena gracilis chloroplast tRNAPhe gene has been determined. We also describe experiments which relate to the effects of the time of hybridization, the stringency of washing, and of base pair mismatches on the hybridization signal.     

Context-dependent mutation rates may cause spurious signatures of a fixation bias favoring higher GC-content in humans

Understanding the proximate and ultimate causes underlying the evolution of nucleotide composition in mammalian genomes is of fundamental interest to the study of molecular evolution. Comparative genomics studies have revealed that many more substitutions occur from G and C nucleotides to A and T nucleotides than the reverse, suggesting that mammalian genomes are not at equilibrium for base composition. Analysis of human polymorphism data suggests that mutations that increase GC-content tend to be at much higher frequencies than those that decrease or preserve GC-content when the ancestral allele is inferred via parsimony using the chimpanzee genome. These observations have been interpreted as evidence for a fixation bias in favor of G and C alleles due to either positive natural selection or biased gene conversion. Here, we test the robustness of this interpretation to violations of the parsimony assumption using a data set of 21,488 noncoding single nucleotide polymorphisms (SNPs) discovered by the National Institute of Environmental Health Sciences (NIEHS) SNPs project via direct resequencing of n = 95 individuals. Applying standard nonparametric and parametric population genetic approaches, we replicate the signatures of a fixation bias in favor of G and C alleles when the ancestral base is assumed to be the base found in the chimpanzee outgroup. However, upon taking into account the probability of misidentifying the ancestral state of each SNP using a context-dependent mutation model, the corrected distribution of SNP frequencies for GC-content increasing SNPs are nearly indistinguishable from the patterns observed for other types of mutations, suggesting that the signature of fixation bias is a spurious artifact of the parsimony assumption.     

Comparison of complex DNA mixtures with generic oligonucleotide microchips.

The reproducibility of melting curves for repeated hybridizations of target DNA with generic oligonucleotide microchips is shown experimentally to depend on the character of matching between fragments of target DNA and immobilized oligonucleotides. The reproducibility of melting curves is higher for the perfect match duplexes and decreases as the number of mismatched pairs within duplexes increases. This effect was applied to the comparative analysis of complex DNA mixtures. We developed a scheme in which we can identify and discriminate between the probe oligonucleotides responsible for the distinctions between target DNA mixtures. A scheme is illustrated by comparing DNA mixtures corresponding to V-D-J genes connected with populations of mRNAs CDR3 TCR Vb (T-cell receptor beta complementarity determining region 3) from the thymus and pancreas of NOD mice. Our results demonstrate that generic microchips can be applied efficiently to the analysis of DNA mixtures.     

Comparison of Complex DNA Mixtures with Generic Oligonucleotide Microchips

Abstract

The reproducibility of melting curves for repeated hybridizations of target DNA with generic oligonucleotide microchips is shown experimentally to depend on the character of matching between fragments of target DNA and immobilized oligonucleotides. The reproducibility of melting curves is higher for the perfect match duplexes and decreases as the number of mismatched pairs within duplexes increases. This effect was applied to the comparative analysis of complex DNA mixtures. We developed a scheme in which we can identify and discriminate between the probe oligonucleotides responsible for the distinctions between target DNA mixtures. A scheme is illustrated by comparing DNA mixtures corresponding to VD-J genes connected with populations of mRNAs CDR3 TCR Vb (T-cell receptor beta complementarity determining region 3) from the thymus and pancreas of NOD mice. Our results demonstrate that generic microchips can be applied efficiently to the analysis of DNA mixtures.     

Rapid capture of DNA targets

A rapid capture technique was developed to efficiently isolate specific DNA targets from a variety of genomes. The specificity can be easily adapted to any target for which partial sequence is known, allowing for the isolation of a wide set of target molecules from either characterized or uncharacterized genomes. These targets include but are not limited to transposable elements, microsatellites, repetitive sequences, and possibly unique sequences. Additionally, because the thermodynamics of nucleic acid hybridizations differ from processes such as PCR, a wider variety of targets with a range of mismatches to any customized probe can be isolated. Further this method allows sequences flanking known internal regions to be co-isolated, facilitating the development of flanking primers for downstream applications. Considerable reduction in the frequency of nonspecific binding between key components (background) obviates the need for subsequent screening steps. Rapid capture of DNA targets quickly provides information about target and flanking sequences.