Synthesis and monitored selection of 5'-nucleobase-capped oligodeoxyribonucleotides

'Caged' peptide nucleic acids activated by red light in a singlet oxygen mediated process

Common 'caged' nucleic acid binders, which can be applied for temporal and spatial control of gene expression, are activated by high energy light (<450 nm). The light of this type is damaging to cells and is strongly absorbed by cellular components. Therefore, shifting the triggering light to the visible region (>550 nm) is highly desirable. Herein we report on a cyclic peptide nucleic acid (PNA), whose backbone contains a 9,10-dialkoxy-substituted anthracene linker. The sequence of this compound was selected to be complementary to a representative microRNA (miR-92). We demonstrated that the cyclic PNA does not bind complementary nucleic acids and is, correspondingly, 'caged'. Its uncaging can be conducted by its exposure to red light (635 nm) in the presence of pyropheophorbide-a. The latter process is mediated by singlet oxygen ((1)O2), which cleaves the 9,10-dialcoxyanthracene linker within the PNA with formation of a linear PNA, an efficient binder of the complementary ribonucleic acid. This is the first example of a red light-activated, 'caged' peptide nucleic acid.

Cu2+-controlled hybridization of peptide nucleic acids

We have prepared cyclic peptide nucleic acids (PNAs). These compounds do not bind complementary nucleic acids. One carboxylic ester group was introduced in the backbone of the cyclic PNAs. This group is cleaved in the presence of Cu(2+) or coordinatively unsaturated Cu(2+) complexes. The cleavage products are linear PNAs. In contrast to the cyclic PNAs, they are efficient nucleic acid binders. The rate of formation of the linear PNAs is proportional to the concentration of the cleaving agents. Therefore, one may apply highly sensitive methods of detection of linear PNAs for determination of Cu(2+) concentration. In particular, we have demonstrated that both fluorescent spectroscopy in combination with molecular beacons and MALDI-TOF mass spectrometry are suitable for the detection of Cu(2+). A range of related divalent metal ions and Eu(3+), Ln(3+), Pr(3+), Ce(3+), and Zr(4+) do not interfere with Cu(2+) detection.

Optimizing the stacking moiety and linker of 2'-acylamido caps of DNA duplexes with 3'-terminal adenine residues

Reported here is the synthesis of oligodeoxynucleotides with a 3'-terminal 2'-acylamido-2'-deoxyadenosine residue. The route to these oligonucleotides employs an N,O-Alloc-protected 5'-phosphoramidite of 2'-amino-2'-deoxyadenosine that was prepared in 11 steps from arabinoadenosine. Small combinatorial libraries of oligonucleotides were generated via acylation with a mixture of linker amino acids and subsequent acylation of their amino groups. Mass spectrometrically monitored nuclease selection assays led to oligonucleotides whose 2'-substituent increases the thermal stability of the DNA duplexes. A linker with three methylene groups between a perylene stacking moiety and the amido group gives a UV-melting point increase of up to 27.9 degrees C for the DNA sequence (TGCGCA*)2, where A* denotes the 2'-acylamidoadenosine residue. The same acylamido group improves mismatch discrimination at the terminal position with a melting point depression of >or=7 degrees C for any of the three mismatches in the target sequence of the octamer 5'-AGGTTGAA-3'. These results demonstrate how even a very weakly base-pairing nucleotide at the 3'-terminus of a DNA probe strand can be enforced to engage in strong and highly sequence-selective base-pairing interactions.

Fluorescent Sensor for Cu2+ with a Tunable Emission Wavelength

A concept of fluorescent metal ion sensing with an easily tunable emission wavelength is presented and its principle demonstrated by detection of Cu(2+). A fluorescein dye was chemically modified with a metal chelating group and then attached to the terminus of ss-DNA. This was combined with a complementary ss-DNA modified with another fluorescent dye (ATTO 590), emitting at a longer wavelength. In the assembled duplex, fluorescence resonance energy transfer (FRET) between the fluorescein donor (excited at 470 nm) and the ATTO 590 acceptor (emitting at 624 nm) is observed. Proper positioning within the rigid DNA double helix prevents intramolecular contact quenching of the two dyes. Coordination of paramagnetic Cu(2+) ions by the chelating unit of the sensor results in direct fluorescence quenching of the fluorescein dye and indirect (by loss of FRET) quenching of the ATTO 590 emission at 624 nm. As a result, emission of the acceptor dye can be used for monitoring of the concentration of Cu(2+), with a 20 nM detection limit. The emission wavelength is readily tuned by replacement of ATTO-DNA by other commercially available DNA-acceptor dye conjugates. Fluorescent metal ion sensors emitting at >600 nm are very rare. The possibility of tuning the emission wavelength is important with respect to the optimization of this sensor type for application to biological samples, which usually show broad autofluorescence at <550 nm.

ChipCheck--a program predicting total hybridization equilibria for DNA binding to small oligonucleotide microarrays

Presented here is the program ChipCheck that allows the computation of total hybridization equilibria for hybridization experiments involving small oligonucleotide arrays. The calculation requires the free energies of binding for all pairs of probes and targets as well as total strand concentrations and probe molecule numbers. ChipCheck has been tested computationally on microarrays with up to 100 spots and 42 target strands (4200 binding equilibria). It arrives at solutions through iterations employing the multidimensional Newton method. While currently running in simulation mode only, an extension of the approach to the exhaustive analysis of chip results is being outlined and may be implemented in the future. The output displays the extent of correct and cross hybridization both graphically and numerically. In principle, calculating total hybridization equilibria allows for eliminating noise from DNA chip results and thus an improvement in sensitivity and accuracy.

Synthesis and DNA binding properties of terminally modified peptide nucleic acids

PNAs with terminal modifications of varying structure and charge were synthesized and their binding to DNA was studied. A variation in thermal stability of 19. 8 degrees C has been observed between the least and the most stable PNA-DNA duplexes. The most stable duplex melts 7.7 degrees C higher than the duplex of the corresponding non-modified PNA and complementary DNA. It has been shown that sequence fidelity of the PNA conjugate having the highest DNA affinity is significantly better than that of non-modified PNA. The results obtained can be used for the design of PNA probes, whose binding to DNA is sequence independent.

Peptide nucleic acid-metal complex conjugates: facile modulation of PNA-DNA duplex stability

Conjugates of peptide nucleic acids (PNA) and metal binding ligands were prepared using solid-phase synthesis. Stability of duplexes of bis-picolylamine-PNA conjugates and DNA was found to be modulated by equimolar concentrations of bioavailable metal ions: Ni(2+), Zn(2+)>Cu(2+). Sequence specificity of PNA was not compromised in the presence of these metal ions.

Synthesis and monitored selection of nucleotide surrogates for binding T:A base pairs in homopurine-homopyrimidine DNA triple helices

A total of 16 oligodeoxyribonucleotides of general sequence 5'-TCTTCTZTCTTTCT-3', where Z denotes an N-acyl-N-(2-hydroxyethyl)glycine residue, were prepared via solid phase synthesis. The ability of these oligonucleotides to form triplexes with the duplex 5'-AGAAGATAGAAAGA-HEG-TCTTTCTATCTTCT-3', where HEG is a hexaethylene glycol linker, was tested. In these triplexes, an 'interrupting' T:A base pair faces the Z residue in the third strand. Among the acyl moieties of Z tested, an anthraquinone carboxylic acid residue linked via a glycinyl group gave the most stable triplex, whose UV melting point was 8.4 degrees C higher than that of the triplex with 5'-TCTTCTGTCTTTCT-3' as the third strand. The results from exploratory nuclease selection experiments suggest that a combinatorial search for strands capable of recognizing mixed sequences by triple helix formation is feasible.

Monitored selection of DNA-hybrids forming duplexes with capped terminal C:G base pairs

Reported here are the results of a search for modified oligodeoxynucleotides with a 5'-terminal cytidine residue whose affinity for target strands is enhanced by 5'-acylamido groups. These acylamido groups were envisioned to act as molecular caps that bind to the exposed terminal base pair of the duplex with the target strand. A total of 52 capped oligonucleotides of the sequence R-CGGTTGAC, where R denotes the 5'-appendage and C a 5'-amino-2',5'-dideoxycytidine residue, were tested. Among the building blocks employed to modify the 5'-amino group of the DNA strand were carboxylic acid residues, either appended directly or via an amino acid residue, and aromatic aldehydes, coupled via reductive amination. The carboxylic acids employed ranged from Fmoc-glycine to (Fmoc)(2)-vancomycin and included a number of aromatic acids and bile acids. Small libraries were subjected to MALDI-monitored nuclease selection experiments, and selected compounds were tested in UV-melting assays with target strands. Cholic acid appendages stabilized terminal C:G base pairs to the greatest extent, with melting point increases of up to 10 degrees C. Further, the cholic acid residue enhanced base pairing fidelity at the terminus, as determined in melting analyses with target strands containing a mismatched nucleobase at the 3'-terminus.