Structure of DNA-Functionalized Dendrimer Nanoparticles

TL;DR

This study uses molecular dynamics simulations to analyze the structure and behavior of DNA-functionalized dendrimer nanoparticles, revealing how DNA wrapping and conformational stability depend on dendrimer generation and charge.

Contribution

It provides detailed atomistic insights into DNA-dendrimer interactions, highlighting the influence of dendrimer charge and size on DNA wrapping and nanoparticle structure.

Findings

G4 dendrimers show more extensive DNA wrapping than G3.

Effective radius of functionalized dendrimers is around 19.5 Å (G3) and 22.4 Å (G4).

DNA strands penetrate dendrimer surfaces, indicating a soft sphere nature.

Abstract

Atomistic molecular dynamics simulations have been carried out to reveal the characteristic features of ethylenediamine (EDA) cored protonated poly amido amine (PAMAM) dendrimers of generation 3 (G3) and 4 (G4) that are functionalized with single stranded DNAs (ssDNAs). The four ssDNA strands that are attached via alkythiolate [-S (CH2)6-] linker molecule to the free amine groups on the surface of the PAMAM dendrimers observed to undergo a rapid conformational change during the 25 ns long simulation period. From the RMSD values of ssDNAs, we find relative stability in the case of purine rich ssDNA strands than pyrimidine rich ssDNA strands. The degree of wrapping of ssDNA strands on the dendrimer molecule was found to be influenced by the charge ratio of DNA and the dendrimer. As G4 dendrimer contains relatively more positive charge than G3 dendrimer, we observe extensive wrapping of ssDNAs on the G4 dendrimer. The ssDNA strands along with the linkers are seen to penetrate the surface of the dendrimer molecule and approach closer to the center of the dendrimer indicating the soft sphere nature of the dendrimer molecule. The effective radius of DNA-functionalized dendrimer nanoparticle was found to be independent of base composition of ssDNAs and was observed to be around 19.5 {\AA} and 22.4 {\AA} when we used G3 and G4 PAMAM dendrimer as the core of the nanoparticle respectively. The observed effective radius of DNA-functionalized dendrimer molecule apparently indicates the significant shrinkage in the structure that has taken place in dendrimer, linker and DNA strands. As a whole our results describe the characteristic features of DNA-functionalized dendrimer nanoparticle and can be used as strong inputs to design effectively the DNA-dendrimer nanoparticle self-assembly for their active biological applications.