Biomimetic artificial organelles with in vitro and in vivo activity triggered by reduction in microenvironment.

Despite tremendous efforts to develop stimuli-responsive enzyme delivery systems, their efficacy has been mostly limited to in vitro applications. Here we introduce, by using an approach of combining biomolecules with artificial compartments, a biomimetic strategy to create artificial organelles (AOs) as cellular implants, with endogenous stimuli-triggered enzymatic activity. AOs are produced by inserting protein gates in the membrane of polymersomes containing horseradish peroxidase enzymes selected as a model for natures own enzymes involved in the redox homoeostasis. The inserted protein gates are engineered by attaching molecular caps to genetically modified channel porins in order to induce redox-responsive control of the molecular flow through the membrane. AOs preserve their structure and are activated by intracellular glutathione levels in vitro. Importantly, our biomimetic AOs are functional in vivo in zebrafish embryos, which demonstrates the feasibility of using AOs as cellular implants in living organisms. This opens new perspectives for patient-oriented protein therapy.

Correction: Bio-catalytic nanocompartments for in situ production of glucose-6-phosphate.

Correction for 'Bio-catalytic nanocompartments for in situ production of glucose-6-phosphate' by M. Lomora et al., Chem. Commun., 2017, 53, 10148-10151.

Bio-catalytic nanocompartments for in situ production of glucose-6-phosphate.

Cells are sophisticated biocatalytic systems driving a complex network of biochemical reactions. A bioinspired strategy to create advanced functional systems is to design confined spaces for complex enzymatic reactions by using a combination of synthetic polymer assemblies and natural cell components. Here, we developed bio-catalytic nanocompartments that contain phosphoglucomutase protected by a biomimetic polymer membrane, which was permeabilized for reactants through insertion of an engineered α-hemolysin pore protein. These bio-catalytic nanocompartments serve for production of glucose-6-phosphate, and thus possess great potential for applications in an incomplete glycolysis, pentose phosphate pathway, or in plant biological reactions.

Polymeric 3D nano-architectures for transport and delivery of therapeutically relevant biomacromolecules.

A promising approach for addressing a range of diseases lies in the delivery of functional biomacromolecules such as nucleic acids or proteins to cells. Polymers, peptides and the different shapes accessible through self-assembly of polymeric and peptidic amphiphiles have been widely explored as carriers and as containers for reactions on the nanoscale. These building blocks are particularly interesting, because several essential parameters such as physical characteristics, conditions for degradation or biocompatibility can be tuned to suit specific requirements. In this review, different three-dimensional architectures ranging from dendrimers and hyperbranched molecules to micelles, vesicles and nanoparticles assembled from synthetic polymers and peptides are discussed. It is focused on their function as a carrier for biologically active macromolecules, highlighting seminal examples from the current literature and pointing out the remaining and upcoming challenges in this important area of research.

Ceria loaded nanoreactors: a nontoxic superantioxidant system with high stability and efficacy.

Medical applications of the superantioxidant ceria nanoparticles (CeNP) are limited due to their high toxicity and low stability. CeNP toxicity is related to their aggregation in solution, and the possible generation of reactive oxygen species (ROS) by a Fenton-like reaction. For the efficient medical application of CeNP, it is necessary to find new solutions, which simultaneously reduce their inherent toxicity while preserving their unique catalytic regenerative qualities. Here we introduce a straightforward strategy based on CeNP encapsulation in polymer vesicles which reduces their toxicity, but preserves their superantioxidant character. We have engineered antioxidant nanoreactors, which serve the dual purpose of: (i) separation of CeNP, which inhibits aggregate formation, and (ii) protection of CeNP from hydrogen peroxide, thus eliminating the Fenton-like reaction which induces cytotoxicity. Nanoreactors containing CeNP possess a higher scavenging activity than free CeNP for both hydroxyl and superoxide radicals, as indicated by spin trapping EPR. Due to the regenerative redox chemistry of ceria, the nanoreactors are active for long periods of time, without requiring additional reducing agents. Upon uptake by cells, the nanoreactors show almost no toxicity compared with the free CeNP after a long term exposure, thus proving their high efficacy as ROS scavengers. Our strategy of engineering CeNP-containing nanoreactors represents a versatile, simple and economical solution to reduce CeNP toxicity, while preserving their functionality; thus nanoreactors are the ideal candidates for fighting oxidative stress in a large variety of medical situations.