Gene
editing with CRISPR/Cas9 is revolutionizing biotechnology and medical
research, yet affordable, efficient, and tailorable delivery systems
are urgently needed to advance translation. Herein, a series of monodisperse
amphiphilic block polymers poly[ethylene oxide-b-2-(dimethylamino)
ethyl methacrylate-b-n-butyl methacrylate]
(PEO-b-PDMAEMA-b-PnBMA) that housed
three PEO lengths (2, 5, and 10 kDa) and a variant lacking PEO (PDMAEMA-b-PnBMA) were synthesized via controlled radical polymerization
and assembled into well-defined spherical cationic micelles. The cationic
micelles were complexed via electrostatic interactions with Cas9 protein/guide
RNA ribonucleoproteins (RNPs) that exhibit anionic charges due to
the overhanging RNA. The resulting micelleplex formulations in both
phosphate-buffered saline (PBS) and water were screened via high content
analysis for gene editing efficiency. The micelle variant with the
10 kDa PEO block offered the highest gene editing performance and
was advanced for in-depth characterization. For the first time, quantitative
static and dynamic light scattering characterization and cryogenic
transmission electron microscopy images of Cas9 protein/guideRNA RNP
loading into well-defined micelleplex nanoparticles are revealed,
where the formulation solvent was found to play a major role in the
physicochemical properties and biological performance. In PBS, the
solutions containing the micelles (63 triblock polymers per micelle)
were assembled with the Cas9 protein/guideRNA RNP payloads offering
uniform loading of 14 RNPs per micelleplex and moderate editing efficiency;
this homogeneous system offers promise for future in vivo/preclinical
applications. Interestingly, when the uniform micelles were formulated
with the RNP payloads in water, larger multimicelleplex nanoparticles
were formed that offered double the editing efficiency of Lipofectamine
2000 (40% gene editing) due to the rapid sedimentation kinetics of
the larger colloids onto adherent cells, offering promising in vitro,
ex vivo, and/or cell therapy applications. This work presents the
first quantitative demonstration of tailorable block polymer micelle
formulations for advancing CRISPR/Cas9 RNP delivery and fundamental
correlation of the solutions physics to biological performance.
Exercise training is well known to affect a suite of physiological and performance traits in mammals, but effects of training in other vertebrate tetrapod groups have been inconsistent. We examined performance and physiological differences among green anole lizards (Anolis carolinensis) that were trained for sprinting or endurance, using an increasingly rigorous training regimen over 8 weeks. Lizards trained for endurance had significantly higher posttraining endurance capacity compared with the other treatment groups, but groups did not show post-training differences in sprint speed. Although acclimation to the laboratory environment and training explain some of our results, mechanistic explanations for these results correspond with the observed performance differences. After training, endurance-trained lizards had higher haematocrit and larger fast glycolytic muscle fibres. Despite no detectable change in maximal performance of sprint-trained lizards, we detected that they had significantly larger slow oxidative muscle fibre areas compared with the other treatments. Treatment groups did not differ in the proportion of number of fibre types, nor in the mass of most limb muscles or the heart. Our results offer some caveats for investigators conducting training research on non-model organisms and they reveal that muscle plasticity in response to training may be widespread phylogenetically.
Polymeric vehicles that efficiently package and controllably release nucleic acids enable the development of safer and more efficacious strategies in genetic and polynucleotide therapies. Developing delivery platforms that endogenously monitor the molecular interactions, which facilitate binding and release of nucleic acids in cells, would aid in the rational design of more effective vectors for clinical applications. Here, we report the facile synthesis of a copolymer containing quinine and 2-hydroxyethyl acrylate that effectively compacts plasmid DNA (pDNA) through electrostatic binding and intercalation. This polymer system poly(quinine-co-HEA) packages pDNA and shows exceptional cellular internalization, transgene expression, and low cytotoxicity compared to commercial controls for several human cell lines, including HeLa, HEK 293T, K562, and keratinocytes (N/TERTs). Using quinine as an endogenous reporter for pDNA intercalation, Raman imaging revealed that proteins inside cells facilitate the unpackaging of polymer–DNA complexes (polyplexes) and the release of their cargo. Our work showcases the ability of this quinine copolymer reporter to not only facilitate effective gene delivery but also enable diagnostic monitoring of polymer–pDNA binding interactions on the molecular scale via Raman imaging. The use of Raman chemical imaging in the field of gene delivery yields unprecedented insight into the unpackaging behavior of polyplexes in cells and provides a methodology to assess and design more efficient delivery vehicles for gene-based therapies.
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