Christian Dose

As Fast and Selective as Enzymatic Ligations: Unpaired Nucleobases Increase the Selectivity of DNA-Controlled Native Chemical PNA Ligation

DNA‐controlled reactions offer interesting opportunities in biological, chemical, and nanosciences. In practical applications, such as in DNA sequence analysis, the sequence fidelity of the chemical‐ligation reaction is of central importance. We present a ligation reaction that is as fast as and much more selective than enzymatic T4 ligase‐mediated oligonucleotide ligations. The selectivity was higher than 3000‐fold in discriminating matched from singly mismatched DNA templates. It is demonstrated that this enormous selectivity is the hallmark of the particular ligation architecture, which is distinct from previous ligation architectures designed as “nick ligations”. Interestingly, the fidelity of the native chemical ligation of peptide nucleic acids was increased by more than one order of magnitude when performing the ligation in such a way that an abasic‐site mimic was formed opposite an unpaired template base. It is shown that the high sequence fidelity of the abasic ligation could facilitate the MALDI‐TOF mass‐spectrometric analysis of early cancer onset by allowing the detection of as little as 0.2 % of single‐base mutant DNA in the presence of 99.8 % wild‐type DNA.

Convergent synthesis of peptide nucleic acids by native chemical ligation.

[reaction: see text] A convergent strategy for synthesizing long contiguous PNA by a native chemical ligation-like technique of PNA segment couplings is presented. This approach required the synthesis of a new PNA-monomer featuring a 1-amino-2-thiol group. It is shown that the additional mercaptomethyl group leaves the hybridization properties of PNA ligation products unaffected. Furthermore, rapid and efficient fluorescence labeling of the ligation products is demonstrated.

Next Generation Hairpin Polyamides with (R)-3,4-Diaminobutyric Acid Turn Unit

The characterization of a new class of pyrrole-imidazole hairpin polyamides with beta-amino-gamma-turn units for recognition of the DNA minor groove is reported. A library of eight hairpins containing ( R)- and ( S)-3,4-diaminobutyric acid (beta-amino-gamma-turn) has been synthesized, and the impact of the molecules on DNA-duplex stabilization was studied for comparison with the parent gamma-aminobutyric acid (gamma-turn) and standard ( R)-2,4-diaminobutyric acid (alpha-amino-gamma-turn)-linked eight-ring polyamides. For some, but not all, sequence compositions, melting temperature analyses have revealed that both enantiomeric forms of the beta-amino-gamma-turn increase the DNA-binding affinity of polyamides relative to the ( R)-alpha-amino-gamma-turn. The ( R)-beta-amine residue may be an attractive alternative for constructing hairpin polyamide conjugates. Biological assays have shown that ( R)-beta-amino-gamma-turn hairpins are able to inhibit androgen receptor-mediated gene expression in cell culture similar to hairpins bearing the standard ( R)-alpha-amino-gamma-turn, from which we infer they are cell-permeable.

New isocysteine building blocks and chemoselective peptide ligation

Boc-, Fmoc- and Cbz-protected isocysteine building blocks were prepared by a concise three-step procedure starting from thiomalic acid. The use of Boc/Trt-protected isocysteine provided convenient access to isocysteinyl peptides that allow the chemoselective ligation of unprotected peptide fragments in water. The pH-dependency of the isocysteine-mediated ligation was compared with that of cysteine-mediated native chemical ligation.

Quantitative Detection of Small Molecule/DNA Complexes Employing a Force-Based and Label-Free DNA-Microarray

Force-based ligand detection is a promising method to characterize molecular complexes label-free at physiological conditions. Because conventional implementations of this technique, e.g., based on atomic force microscopy or optical traps, are low-throughput and require extremely sensitive and sophisticated equipment, this approach has to date found only limited application. We present a low-cost, chip-based assay, which combines high-throughput force-based detection of dsDNA.ligand interactions with the ease of fluorescence detection. Within the comparative unbinding force assay, many duplicates of a target DNA duplex are probed against a defined reference DNA duplex each. The fractions of broken target and reference DNA duplexes are determined via fluorescence. With this assay, we investigated the DNA binding behavior of artificial pyrrole-imidazole polyamides. These small compounds can be programmed to target specific dsDNA sequences and distinguish between D- and L-DNA. We found that titration with polyamides specific for a binding motif, which is present in the target DNA duplex and not in the reference DNA duplex, reliably resulted in a shift toward larger fractions of broken reference bonds. From the concentration dependence nanomolar to picomolar dissociation constants of dsDNA.ligand complexes were determined, agreeing well with prior quantitative DNAase footprinting experiments. This finding corroborates that the forced unbinding of dsDNA in presence of a ligand is a nonequilibrium process that produces a snapshot of the equilibrium distribution between dsDNA and dsDNA.ligand complexes.

DNA sequence selectivity of hairpin polyamide turn units

A class of hairpin polyamides linked by 3,4-diaminobutyric acid, resulting in a beta-amine residue at the turn unit, showed improved binding affinities relative to their alpha-amino-gamma-turn analogs for particular sequences. We incorporated beta-amino-gamma-turns in six-ring polyamides and determined whether there are any sequence preferences under the turn unit by quantitative footprinting titrations. Although there was an energetic penalty for G.C and C.G base pairs, we found little preference for T.A over A.T at the beta-amino-gamma-turn position. Fluorine and hydroxyl substituted alpha-amino-gamma-turns were synthesized for comparison. Their binding affinities and specificities in the context of six-ring polyamides demonstrated overall diminished affinity and no additional specificity at the turn position. We anticipate that this study will be a baseline for further investigation of the turn subunit as a recognition element for the DNA minor groove.

DNA-templated native chemical ligation of functionalized peptide nucleic acids: a versatile tool for single base-specific detection of nucleic acids.

Single base-specific detection of DNA/RNA sequences is of importance in the diagnosis of disease-associated genetic disorders or early stage cancer. This chapter introduces DNA-templated native chemical PNA ligation as a potentially useful tool for the sequence specific detection of nucleic acids. The template-induced alignment of PNA-thioesters and 1,2-aminothiol-PNAs in close proximity leads to an increase in their effective molarities. This facilitates PNA ligation to proceed at concentrations where no reaction would be possible in absence of the template. Moreover, hybridization of the rather short PNA conjugates with non-complementary DNA/RNA is disfavored, which prevents PNA ligation to occur on single base-mismatched templates. Different readout strategies of the ligation reaction such as HPLC, MALDI-TOF-MS and fluorecence monitoring are discussed, and examples for the detection of a point mutation within single stranded and PCR-amplified double stranded DNA are provided.