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Interpreting the Rich Behavior of Ternary DNA-PEI-Fe(III) Complexes

This work aims to shed light on the mechanism of interaction between components of ternary DNA-PEI-Fe(III) complexes, using experimental and theoretical approaches. In the experimental part, the chelation between PEI-Fe(III) was inspected by potentiometry and electrical conductance measurements and...

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Published in:	Biomacromolecules 2014-02, Vol.15 (2), p.478-491
Main Authors:	Jorge, Andreia F, Pereira, Rui F. P, Nunes, Sandra C. C, Valente, Artur J. M, Dias, Rita S, Pais, Alberto A. C. C
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Language:	English
Subjects:	Applied sciences Biological and medical sciences DNA - chemistry Exact sciences and technology Ferric Compounds - chemistry General pharmacology Medical sciences Monte Carlo Method Organic polymers Pharmaceutical technology. Pharmaceutical industry Pharmacology. Drug treatments Physicochemistry of polymers Polyethyleneimine - chemistry Properties and characterization Solution and gel properties
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creator	Jorge, Andreia F Pereira, Rui F. P Nunes, Sandra C. C Valente, Artur J. M Dias, Rita S Pais, Alberto A. C. C
description	This work aims to shed light on the mechanism of interaction between components of ternary DNA-PEI-Fe(III) complexes, using experimental and theoretical approaches. In the experimental part, the chelation between PEI-Fe(III) was inspected by potentiometry and electrical conductance measurements and the respective importance for the condensation of DNA analyzed. To this end, three different mixing protocols for the components were imposed using different PEIs, branched (bPEI1.2 and bPEI10) and linear (lPEI2.5 and lPEI25). A delay in DNA condensation was observed when PEI and Fe(III) were premixed and then added to DNA. The set of observations was complemented by determination of the amount of Fe(III) included in the polyplexes, which was found to be dependent on the order of mixture and on the type of PEI used, decreasing with intrinsic PEI condensation efficiency. Overall, a coherent picture in which Fe(III) compensates PEI, probably modulating the respective charge, emerges. Some points arisen from the experimental part were rationalized using Monte Carlo simulations. Different architectured polycation (PC) chains were modeled and an interaction between PC and multivalent ions, mimicking the chelation of Fe(III) by the PEI, was imposed. It was found that chelation enhances polyanion (PA) compaction, irrespective of the PC architecture and charge density. The amount of multivalent ions in each polyplex compensates the negative charge unbalanced by the PC. The charge density and the ability of chelation of each PC dictate the disposition of each condensing agent along the PA backbone, and their coexistence strengthens PA compaction. The deep understanding of these ternary mixtures is a step forward in the optimization of such systems for application in gene delivery.
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P ; Nunes, Sandra C. C ; Valente, Artur J. M ; Dias, Rita S ; Pais, Alberto A. C. C</creator><creatorcontrib>Jorge, Andreia F ; Pereira, Rui F. P ; Nunes, Sandra C. C ; Valente, Artur J. M ; Dias, Rita S ; Pais, Alberto A. C. C</creatorcontrib><description>This work aims to shed light on the mechanism of interaction between components of ternary DNA-PEI-Fe(III) complexes, using experimental and theoretical approaches. In the experimental part, the chelation between PEI-Fe(III) was inspected by potentiometry and electrical conductance measurements and the respective importance for the condensation of DNA analyzed. To this end, three different mixing protocols for the components were imposed using different PEIs, branched (bPEI1.2 and bPEI10) and linear (lPEI2.5 and lPEI25). A delay in DNA condensation was observed when PEI and Fe(III) were premixed and then added to DNA. The set of observations was complemented by determination of the amount of Fe(III) included in the polyplexes, which was found to be dependent on the order of mixture and on the type of PEI used, decreasing with intrinsic PEI condensation efficiency. Overall, a coherent picture in which Fe(III) compensates PEI, probably modulating the respective charge, emerges. Some points arisen from the experimental part were rationalized using Monte Carlo simulations. Different architectured polycation (PC) chains were modeled and an interaction between PC and multivalent ions, mimicking the chelation of Fe(III) by the PEI, was imposed. It was found that chelation enhances polyanion (PA) compaction, irrespective of the PC architecture and charge density. The amount of multivalent ions in each polyplex compensates the negative charge unbalanced by the PC. 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source	American Chemical Society:Jisc Collections:American Chemical Society Read & Publish Agreement 2022-2024 (Reading list)
subjects	Applied sciences Biological and medical sciences DNA - chemistry Exact sciences and technology Ferric Compounds - chemistry General pharmacology Medical sciences Monte Carlo Method Organic polymers Pharmaceutical technology. Pharmaceutical industry Pharmacology. Drug treatments Physicochemistry of polymers Polyethyleneimine - chemistry Properties and characterization Solution and gel properties
title	Interpreting the Rich Behavior of Ternary DNA-PEI-Fe(III) Complexes
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