Physicochemical characterization of thermoresponsive poly(N-isopropylacrylamide)-poly(ethylene imine) graft copolymers.

Synthetic polycations have shown promise as gene delivery vehicles but suffer from an unacceptable toxicity and low transfection efficiency. Novel architectures are being explored to increase transfection efficiency, including copolymers with a thermoresponsive character. The physicochemical characterization of a family of copolymers comprising a core of the cationic polymer poly(ethylene imine) (PEI) with differing thermoresponsive poly( N-isopropylacrylamide) (PNIPAM) grafts has been carried out using pulsed-gradient spin-echo NMR (PGSE-NMR) and small-angle neutron scattering (SANS). For the copolymers that have longer chain PNIPAM grafts, there is clear evidence of the collapse of the grafts with increasing temperature and the associated emergence of an attractive interpolymer interaction. These facets depend on the number of PNIPAM grafts attached to the PEI core. While a collapse in the smaller PNIPAM grafts is observed for the third polymer, there is no appearance of the interpolymer attractive interaction. These observations provide further insight into the association behavior of these copolymers, which is fundamental to developing a full understanding of how they interact with nucleic acids. Furthermore, the differing behaviors of the three copolymers over temperatures in which the PNIPAM blocks undergo coil-to-globule transitions is indicative of changes in the presentation of charged-core and hydrophobic chain components, which are key factors affecting nucleic acid binding and, ultimately, cell transfection ability.

Avidin bioconjugate with a thermoresponsive polymer for biological and pharmaceutical applications.

A thermoresponsive polymer, N-isopropylacrylamide-co-acrylamide (Mn 6 kDa) with a lower critical solution temperature (LCST) of 37 degrees C, was activated and conjugated to avidin to yield a derivative with 200 kDa molecular weight. Gel permeation analysis demonstrated that the new bioconjugate possessed an apparent size corresponding to a 220 kDa globular protein. Photon correlation spectroscopy and turbidometric studies showed that the bioconjugate underwent temperature dependent phase transitions. The protein-co-polymer bioconjugate displayed the same onset phase transition temperature (LCST) as the original synthetic co-polymer. Nevertheless, the aggregation profile of the bioconjugate shifted at higher temperature as compared to the original polymer. This indicated that the aggregation behaviour coil-to-globule transition of the co-polymer was modified by anchoring to the protein surface. Circular dichroism analysis showed that the co-polymer conjugation did not alter the protein tertiary structure tertiary the aromatic amino acid environment. The bioconjugate maintained 85+/-3% of native avidin affinity for biotin and biotin-Mab, and high affinity was maintained after three heating cycles. Pharmacokinetic studies demonstrated that the co-polymer bioconjugation increased the avidin residence time in the bloodstream. The distribution phase of avidin-co-polymer was longer than the native protein by a factor of 20. The co-polymer conjugation decreased by three-fold the distribution extent of avidin and reduced significantly its up-take to the liver.

Enhanced gene expression through temperature profile-induced variations in molecular architecture of thermoresponsive polymer vectors.

BACKGROUND: Successful non-viral gene targeting requires vectors to meet two conflicting needs-strong binding to protect the genetic material during transit and weak binding at the target site to enable release. Responsive polymers could fulfil such requirements through the switching of states, e.g. the chain-extended coil to chain-collapsed globule phase transition that occurs at a lower critical solution temperature (LCST), in order to transport nucleic acid in one polymer state and release it in another. METHODS: The ability of new synthetic polycations based on poly(ethyleneimine) (PEI) with grafted neutral responsive poly(N-isopropylacrylamide) (PNIPAm) chains to condense DNA into particles with architectures varying according to graft polymer LCST was assessed using a combination of fluorescence spectroscopy, dynamic light scattering (DLS), zeta sizing, gel retardation and atomic force microscopy studies. Transfection assays were conducted under experimental conditions wherein the polymer components were able to cycle across their LCST. RESULTS: Two PEI-PNIPAm conjugate polymers with different LCSTs displayed coil-globule transitions when complexed to plasmid DNA, leading to variations in molecular architecture as shown by changes in emission maxima of an environment-sensitive fluorophore attached to the PNIPAm chains. Gel retardation assays demonstrated differences in electrophoretic mobilities of polymer-DNA complexes with temperatures below and above polymer LCSTs. Atomic force micrographs showed changes in the structures of polymer-DNA complexes for a polymer undergoing a phase transition around body temperature but not for the polymer with LCST outside this range. Transfection experiments in C2C12 and COS-7 cells demonstrated that the highest expression of transgene occurred in an assay that involved a 'cold-shock' below polymer LCST during transfection. CONCLUSIONS: Designed changes in thermoresponsive polycation vector configuration via temperature-induced phase transitions enhanced transgene expression. The results indicate that changes in molecular architecture induced by a carefully chosen stimulus during intracellular trafficking can be used to enhance gene delivery.

Synthesis and characterization of variable-architecture thermosensitive polymers for complexation with DNA.

Copolymers of N-isopropylacrylamide with a fluorescent probe monomer were grafted to branched poly(ethyleneimine) to generate polycations that exhibited lower critical solution temperature (LCST) behavior. The structures of these polymers were confirmed by spectroscopy, and their phase transitions before and after complexation with DNA were followed using ultraviolet and fluorescence spectroscopy and light scattering. Interactions with DNA were investigated by ethidium bromide displacement assays, while temperature-induced changes in structure of both polymers and polymer-DNA complexes were evaluated by fluorescence spectroscopy, dynamic light scattering, laser Doppler anemometry, and atomic force microscopy (AFM) in water and buffer solutions. The results showed that changes in polymer architecture were mirrored by variations in the architectures of the complexes and that the overall effect of the temperature-mediated changes was dependent on the graft polymer architecture and content, as well as the solvent medium, concentrations, and stoichiometries of the complexes. Furthermore, AFM indicated subtle changes in polymer-DNA complexes at the microstructural level that could not be detected by light scattering techniques. Uniquely, variable-temperature aqueous-phase AFM was able to show that changes in the structures of these complexes were not uniform across a population of polymer-DNA condensates, with isolated complexes compacting above LCST even though the sample as a whole showed a tendency for aggregation of complexes above LCST over time. These results indicate that sample heterogeneities can be accentuated in responsive polymer--DNA complexes through LCST-mediated changes--a factor that is likely to be important in cellular uptake and nucleic acid transport.

Thermoresponsive polymers as gene delivery vectors: cell viability, DNA transport and transfection studies.

A range of gene delivery vectors containing the thermoresponsive polymer, poly(N-isopropylacrylamide) (PNIPAm) was evaluated for effects on cell viability, intracellular trafficking and transgene expression in C2C12 mouse muscle cells. Polymers were complexed with plasmid DNA at pH 7.4 and the ability of the resulting particles to transfect cells was assessed via confocal microscopy and protein expression studies in tissue culture. Cell viability assays indicated that these polymers were toxic at high concentrations when not complexed to DNA or at certain polymer:DNA ratios. Poly(ethyleneimine) co-polymers with side-chain grafted PNIPAm were shown to be less toxic than poly(ethyleneimine) alone or PNIPAm-co-(N,N'-dimethylaminoethylmethacrylate) linear co-polymers and the effects were concentration dependent. Confocal micrographs of labeled polymers and DNA indicated rapid cellular entry for all the complexes but expression of Green Fluorescent Protein was achieved only when the branched PEI-PNIPAm co-polymers were used as vectors. The results indicate that design of appropriate co-polymer components and overall polymer architecture can be used to mediate, and perhaps ultimately control, DNA transport and transgene expression.

Control of a multisubunit DNA motor by a thermoresponsive polymer switch.

The conjugation of thermoresponsive polymers to multisubunit, multifunctional hybrid type 1 DNA restriction-modification (R-M) enzymes enables temperature-controlled "switching" of DNA methylation by the conjugate. Polymers attached to the enzyme at a subunit distal to the methylation subunit allow retention of DNA recognition and ATPase activity while controlling methylation of plasmid DNA. This regulation of enzyme activity arises from the coil-globule phase transitions of the polymer as shown in light scattering and gel retardation assays.

Protein-polymer nano-machines. Towards synthetic control of biological processes.

The exploitation of nature's machinery at length scales below the dimensions of a cell is an exciting challenge for biologists, chemists and physicists, while advances in our understanding of these biological motifs are now providing an opportunity to develop real single molecule devices for technological applications. Single molecule studies are already well advanced and biological molecular motors are being used to guide the design of nano-scale machines. However, controlling the specific functions of these devices in biological systems under changing conditions is difficult. In this review we describe the principles underlying the development of a molecular motor with numerous potential applications in nanotechnology and the use of specific synthetic polymers as prototypic molecular switches for control of the motor function. The molecular motor is a derivative of a TypeI Restriction-Modification (R-M) enzyme and the synthetic polymer is drawn from the class of materials that exhibit a temperature-dependent phase transition.The potential exploitation of single molecules as functional devices has been heralded as the dawn of new era in biotechnology and medicine. It is not surprising, therefore, that the efforts of numerous multidisciplinary teams 12. have been focused in attempts to develop these systems. as machines capable of functioning at the low sub-micron and nanometre length-scales 3. However, one of the obstacles for the practical application of single molecule devices is the lack of functional control methods in biological media, under changing conditions. In this review we describe the conceptual basis for a molecular motor (a derivative of a TypeI Restriction-Modification enzyme) with numerous potential applications in nanotechnology and the use of specific synthetic polymers as prototypic molecular switches for controlling the motor function 4.