Preliminary studies on noncovalent hyperbranched polymers based on PNA and DNA building blocks

Synthesis and characterization of a novel ester-based nucleoamino acid for the assembly of aromatic nucleopeptides for biomedical applications

In this work, we report a technological approach to a novel Fmoc-protected nucleoamino acid, based on l-tyrosine, carrying the DNA nucleobase on the hydroxyl group by means of an ester bond, suitable for the solid-phase synthesis of novel aromatic nucleopeptides of potential interest in biomedicine. After ESI-MS and NMR characterization this building block was used for the assembly of a thymine-functionalized tetrapeptide, composed of nucleobase-containing and underivatized l-tyrosine moieties alternated in the backbone.

Synthesis, biological evaluation and supramolecular assembly of novel analogues of peptidyl nucleosides

This work concerns the synthesis, the supramolecular assembly and the evaluation of some biological properties, such as DNA and RNA-binding ability and human serum stability, of novel nucleopeptides. These compounds are of potential interest for the well-known properties that similar compounds, such as natural peptidyl nucleosides, possess in biology and medicine and also for the possibility to realize nucleopeptide-based supramolecular systems useful for drug and gene delivery applications. More particularly, all four nucleobase-containing peptides were synthesized by solid phase synthesis, purified by HPLC and characterized by NMR and ESI-MS. Subsequently, nucleopeptide self-assembly as well as DNA and RNA-binding ability were investigated by CD spectroscopy and further information on the formation of molecular networks, based on the peptidyl nucleoside analogues and nucleic acids, was obtained by Laser Light Scattering. Finally, nucleopeptide enzymatic stability was studied and a half life of about 2 hours was found in the presence of 50% fresh human serum.

Evidences for supramolecular organization of nucleopeptides: synthesis, spectroscopic and biological studies of a novel dithymine L-serine tetrapeptide

This work concerns a dithymine tetrapeptide, which can be seen as a new analogue of a dinucleoside monophosphate, made of both unfunctionalized and thymine-containing L-serine units alternated in the sequence. The new nucleopeptide was obtained on the solid phase by two different synthetic strategies. The first one is suitable to easily realize nucleopeptides with homonucleobase sequences, obtained by assembling an oligoserine backbone and then simultaneously coupling the free serine hydroxyl groups with the carboxymethylated nucleobase. The other strategy, which makes use of a Fmoc-protected nucleo-L-serine monomer, allows for the obtainment of nucleopeptides with mixed nucleobase sequences. CD spectroscopic studies and laser light scattering experiments, performed on solutions of the novel nucleopeptide, suggested the formation of supramolecular networks based on the self-assembly of the dithymine tetrapeptide molecules. Furthermore, CD binding studies with natural nucleic acids revealed a very weak interaction between the nucleopeptide and DNA (but not RNA). Molecular networks based on this biodegradable and water-soluble nucleopeptide, which is more resistant in plasma than standard tetrapeptides (and oligopeptides), contain a hydrophobic core which could provide the necessary environment to incorporate poorly water-soluble drugs, as evidenced by fluorescence spectroscopy. Furthermore, our studies evidenced that the structure of the tetrapeptide-based supramolecular assembly can be modified by metal ions as evidenced by UV interaction studies with Cu(2+).