Eylon Yavin

A Metal-Free DNA Nuclease Based on a Cyclic Peptide Scaffold

The ability to cleave DNA with the aid of chemical nucleases has been a challenge in the scientific community, particularly in the absence of a redox active metal ion. Inspired by structural characterization of the active site found in Staphylococcal nuclease, we have designed a series of organic molecule comprising cyclic pentapeptides conjugated to a DNA intercalator (e.g., anthraquinone). The cyclic peptide is designed to cleave the phosphodiester backbone, whereas the intercalator is expected to improve binding affinity to the substrate (DNA). Our lead compound (1-AQ), composed of the cyclic peptide cyc-d-Lys-Gly-Arg-Ser-Arg conjugated to anthraquinone, degrades DNA into small fragments at physiologically relevant conditions (i.e., 37 degrees C, pH = 7.4). We find that 1-AQ is highly effective in degrading duplex DNA at micromolar concentrations as corroborated by agarose and polyacrylamide gel electrophoresis. Changing the DNA intercalator to acridine (1-Ac) renders the compound comparable in nuclease activity to 1-AQ. In comparison to control compounds (Lin-1 and 1) that lack either the cyclic scaffold or the DNA intercalator, our lead compound (1-AQ) is found to be significantly more active as a DNA chemical nuclease. We have studied the importance of the triad (Arg-Ser-Arg) as the designed module for DNA cleavage. Changing l-Ser to l-Glu (cyc-d-Lys-Gly-Arg-Glu-Arg, Glu-AQ) results in an inactive compound, whereas the cyclic peptide Gly-AQ (cyc-d-Lys-Gly-Arg-Gly-Arg, where glycine replaces l-serine) has similar DNA nuclease activity to 1-AQ. In addition, changing the stereochemistry from d-lysine to l-lysine results in a cyclic peptide (1-L-AQ) exerting weak DNA nuclease activity, highlighting the importance of the cyclic backbone conformation for efficient DNA nuclease activity. The addition of ROS scavengers does not reduce DNA nuclease activity; an observation that supports a hydrolytic cleavage mechanism. Finally, we have estimated the kinetics of DNA cleavage of a 15-mer duplex DNA substrate by compound 1-AQ. By monitoring DNA duplex degradation by following the change in absorbance (hyperchromicity) at various 1-AQ concentrations, we report a maximal k(obs) value (as an underestimation of k(max)) of 1.62 h(-1) at a 7.5-fold of 1-AQ. We have also compared the other two active peptide conjugates, namely, 1-Ac and Gly-AQ to that of 1-AQ. Both compounds exert similar nuclease activity to that of 1-AQ. To the best of our knowledge, this is the most active metal-free DNA nuclease reported to date that exerts its DNA nuclease activity at biologically relevant conditions.

DNA Photocleavage by DNA and DNA−LNA Amino Acid−Dye Conjugates

DNA photocleavage by triplex forming oligonucleotides (TFO) has potential implications in both biotechnology and medicine. We have synthesized a series of homopurine DNA and DNA/LNA 14-mers to which an amino acid (glycine or l-tryptophan) and a cyanine dye are covalently linked. Two cyanine dyes were examined that include a quinolinium ring linked to a benzothiazolium ring through a monomethine (TO1) or trimethine (TO2) linker. The 14-mer sequence was chosen to target mdm2, a ubiquitin ligase (E3) that regulates p53 by promoting its ubiquitylation and proteosomal degradation. Such inhibition has been previously proposed as a therapeutic approach to target wild-type p53-expressing cancers. To examine whether our TFO conjugates photocleave the mdm2 target, we incubated the various conjugates with the mdm2 plasmid and irradiated the samples with visible light. We show that only the TFO with the complementary sequence and with an intervening l-tryptophan leads to the linearization of the plasmid after a short irradiation time (10 min) exciting the dye (lambda(max)(TO1) = 500 nm and lambda(max)(TO2) = 630 nm) with visible light. Furthermore, the photoreactivity is more pronounced for the LNA/DNA conjugate, an observation that is consistent with improved hybridization to the DNA target. Sequence specificity of the photoreaction is further corroborated on a synthetic 44-mer duplex containing the TFO site. Evidence for a ROS-dependent mechanism is also given and discussed.

PNA–Rose Bengal Conjugates as Efficient DNA Photomodulators

Selective photoinduced modulation of DNA may provide a powerful therapeutic tool allowing spatial and temporal control of the photochemical reaction. We have explored the photoreactivity of peptide nucleic acid (PNA) conjugates that were conjugated to a highly potent photosensitizer, Rose Bengal (RB). In addition, a short PEGylated peptide (K-PEG8-K) was conjugated to the C-terminus of the PNA to improve its water solubility. A short irradiation (visible light) of PNA conjugates with a synthetic DNA resulted in highly efficient photomodulation of the DNA as evidenced by polyacrylamide gel electrophoresis (PAGE). In addition, a PNA-RB conjugate replacing K-PEG8-K with four l-glutamic acids (E4) was found to be photoinactive. Irradiation of active PNA-RB conjugates with synthetic DNA in D20 augments the photoactivity; supporting the involvement of singlet oxygen. PAGE, HPLC, and MALDI-TOF analyses indicate that PNA-DNA photo-cross-linking is a significant pathway in the observed photoreactivity. Selective photo-cross-linking of such PNA-RB conjugates may be a novel approach to selective photodynamic therapy (sPDT) as such molecules would be sequence-specific, cell-permeable, and photoactivated in the visible region.

CLIP6-PNA-Peptide Conjugates: Non-Endosomal Delivery of Splice Switching Oligonucleotides

Efficient delivery of oligonucleotides still remains a challenge in the field of oligonucleotide based therapy. Peptide nucleic acid (PNA), a DNA analogue that is typically synthesized by solid phase peptide chemistry, has been conjugated to a variety of cell penetrating peptides (CPP) as a means of improving its cellular uptake. These CPPs typically deliver their cargoes into cells by an endosomal-dependent mechanism resulting in lower bioavailability of the cargo. Herein, we designed and synthesized PNA-peptide conjugates as splice switching oligonucleotides (SSO) targeting the Mnk2 gene, a therapeutic target in cancer. In humans, the MKNK2 gene, is alternatively spliced, generating isoforms with opposite biological activities: Mnk2a and Mnk2b. It was found that the Mnk2a isoform is down-regulated in breast, lung, brain, and colon tumors and is a tumor suppressor, whereas MnK2b is oncogenic. We have designed and synthesized PNAs that were conjugated to either of the following peptides: a nuclear localization sequence (NLS) or a cytosol localizing internalization peptide (CLIP6). CLIP6-PNA demonstrates effective cellular uptake and exclusively employs a nonendosomal mechanism to cross the cellular membranes of glioblastoma cells (U87). Simple incubation of PNA-peptide conjugates in human glioblastoma cells up-regulates the Mnk2a isoform leading to cancer cell death.