Influence of DNA Type on the Physicochemical and Biological Properties of Polyplexes Based on Star Polymers Bearing Different Amino Functionalities.
Emi HaladjovaSilvia PanseriMonica MontesiArianna RossiAthanasios SkandalisStergios PispasStanislav RangelovPublished in: Polymers (2023)
The interactions of two star polymers based on poly (2-(dimethylamino)ethyl methacrylate) with different types of nucleic acids are investigated. The star polymers differ only in their functionality to bear protonable amino or permanently charged quaternary ammonium groups, while DNAs of different molar masses, lengths and topologies are used. The main physicochemical parameters of the resulting polyplexes are determined. The influence of the polymer' functionality and length and topology of the DNA on the structure and properties of the polyelectrolyte complexes is established. The quaternized polymer is characterized by a high binding affinity to DNA and formed strongly positively charged, compact and tight polyplexes. The parent, non-quaternized polymer exhibits an enhanced buffering capacity and weakened polymer/DNA interactions, particularly upon the addition of NaCl, resulting in the formation of less compact and tight polyplexes. The cytotoxic evaluation of the systems indicates that they are sparing with respect to the cell lines studied including osteosarcoma, osteoblast and human adipose-derived mesenchymal stem cells and exhibit good biocompatibility. Transfection experiments reveal that the non-quaternized polymer is effective at transferring DNA into cells, which is attributed to its high buffering capacity, facilitating the endo-lysosomal escape of the polyplex, the loose structure of the latter one and weakened polymer/DNA interactions, benefitting the DNA release.
Keyphrases
- circulating tumor
- cell free
- single molecule
- adipose tissue
- dna methylation
- metabolic syndrome
- induced apoptosis
- genome wide
- magnetic resonance imaging
- mass spectrometry
- skeletal muscle
- endoplasmic reticulum stress
- minimally invasive
- atomic force microscopy
- high resolution
- dna binding
- solid state
- tissue engineering
- bone loss
- anti inflammatory