Effect of different molecular weight ß-glucan hydrated with highland barley protein on the quality and in vitro starch digestibility of whole wheat bread.

Whole wheat bread has high nutritional value, but it has inferior baking quality and high glycemic index, which needs to be improved by methods such as adding protein and ß-glucan. This study investigated the effects of ß-glucan and highland barley protein of different molecular weights (2 × 104, 1 × 105, and 3 × 105 Da) and different hydrate methods (pre-hydrate and not pre-hydrate) on the characteristics of whole wheat dough and bread. The mixing properties and rheological properties demonstrated that ß-glucan pre-hydrated with highland barley protein were able to reduce the dough tan δ, reduce the dough viscoelasticity, while enhance the gluten network structure and dough deformation resistance. Compared to the control sample, the medium molecular weight pre-hydrate bread had a better specific volume of 3.21 mL/g, lower hardness of 527.28 g. In vitro starch digestion characteristics and ATR-FTIR showed that low and high molecular weight pre-hydrate increased the short-range ordered structure of starch and reduced the starch digestibility, while not pre-hydrated medium molecular weight hydrate had the lowest level of starch digestibility.

Cell Free Expression in Proteinosomes Prepared from Native Protein-PNIPAAm Conjugates.

Towards the goal of building synthetic cells from the bottom-up, the establishment of micrometer-sized compartments that contain and support cell free transcription and translation that couple cellular structure to function is of critical importance. Proteinosomes, formed from crosslinked cationized protein-polymer conjugates offer a promising solution to membrane-bound compartmentalization with an open, semi-permeable membrane. Critically, to date, there has been no demonstration of cell free transcription and translation within water-in-water proteinosomes. Herein, a novel approach to generate proteinosomes that can support cell free transcription and translation is presented. This approach generates proteinosomes directly from native protein-polymer (BSA-PNIPAAm) conjugates. These native proteinosomes offer an excellent alternative as a synthetic cell chassis to other membrane bound compartments. Significantly, the native proteinosomes are stable under high salt conditions that enables the ability to support cell free transcription and translation and offer enhanced protein expression compared to proteinosomes prepared from traditional methodologies. Furthermore, the integration of native proteinosomes into higher order synthetic cellular architectures with membrane free compartments such as liposomes is demonstrated. The integration of bioinspired architectural elements with the central dogma is an essential building block for realizing minimal synthetic cells and is key for exploiting artificial cells in real-world applications.

Protocells Capable of Generating a Cytoskeleton-like Structure from intracellular Membrane-active Artificial Organelles.

The intricate nature of eukaryotic cells with differently viscous intracellular compartments provides (membrane-active) enzymes to trigger time- and concentration-dependent processes in the intra-/extracellular matrix. Herein, we capitalize on membrane-active artificial organelles (AOs) to develop fluidic and stable proteinaceous membrane-based protocells. AOs in protocells induce the self-assembly of oligopeptides into an artificial cytoskeleton that underline their influence on the structure and functionality of protocells. A series of microscopical tools is used to validate the intracellular assembly and distribution of cytoskeleton, the changing protocells morphology, and AOs inclusion within cytoskeletal growth. Thus, the dynamics, diffusion and viscosity of intracellular components in the presence of cytoskeleton are evaluated by fluorescence tools and enzymatic assay. Membrane-active alkaline phosphatase in polymersomes as AOs fulfills the requirements of biomimetic eukaryotic cells to trigger intracellular environment, mobility, viscosity, diffusion and enzymatic activity itself as well as high mechanical stability and high membrane fluidity of protocells. Thus membrane-active AOs in protocells thoroughly provide a variable reaction space in a changing intracellular environment and underline their regulatory role in the fabrication of complex protocell architectures and functions. This study demonstrates an important contribution to effective biomimicry of cell-like structures, shapes and functions.

Programmable synthetic cell networks regulated by tuneable reaction rates.

Coupled compartmentalised information processing and communication via molecular diffusion underpin network based population dynamics as observed in biological systems. Understanding how both compartmentalisation and communication can regulate information processes is key to rational design and control of compartmentalised reaction networks. Here, we integrate PEN DNA reactions into semi-permeable proteinosomes and characterise the effect of compartmentalisation on autocatalytic PEN DNA reactions. We observe unique behaviours in the compartmentalised systems which are not accessible under bulk conditions; for example, rates of reaction increase by an order of magnitude and reaction kinetics are more readily tuneable by enzyme concentrations in proteinosomes compared to buffer solution. We exploit these properties to regulate the reaction kinetics in two node compartmentalised reaction networks comprised of linear and autocatalytic reactions which we establish by bottom-up synthetic biology approaches.

Expansion STED microscopy (ExSTED).

The recently developed expansion microscopy method (ExM) allows for the resolution of structures below the diffraction limit of light not by sophisticated instrumentation, but rather by physically expanding the molecular structure of cells. This happens by crosslinking the protein in the sample to a hydrogel that is polymerized in situ and subsequently expanded, tearing the proteins apart in a nearly isotropic manner. In the resulting, larger facsimile of the original sample, the fluorescence-labeled molecules of interest can be optically separated by conventional fluorescence microscopy since the intermolecular distances are enlarged by a factor ranging from ~4 to 20 depending on the chemistry used for the hydrogel. The achieved improvement in resolution thus corresponds to the expansion factor. Further increase in resolution beyond this value may be achieved by combining ExM with established super-resolution microscopy methods. Indeed, this is possible using structured illumination microscopy (SIM) (Halpern et al., 2017; Wang et al., 2018), single molecule localization microscopy (SMLM) (Zwettler et al., 2020) and stimulated emission depletion (STED), as we and others have shown recently (Gambarotto et al., 2019; Gao et al., 2018; Kim, Kim, Lee, & Shim, 2019; Unnersjö-Jess et al., 2016). Here, we provide a protocol, for our method, called ExSTED, which enabled us to achieve an increase in resolution of up to 30-fold compared to conventional microscopy, well beyond what is possible with conventional STED microscopy. Our protocol includes a strategy to achieve very high intensity fluorescence labeling, which is essential for optimal signal retention during the expansion process for ExSTED.

Expansion Stimulated Emission Depletion Microscopy (ExSTED).

Stimulated emission depletion (STED) microscopy is routinely used to resolve the ultrastructure of cells with a ∼10-fold higher resolution compared to diffraction limited imaging. While STED microscopy is based on preparing the excited state of fluorescent probes with light, the recently developed expansion microscopy (ExM) provides subdiffraction resolution by physically enlarging the sample before microscopy. The expansion of the fixed cells by cross-linking and swelling of hydrogels easily enlarges the sample ∼4-fold and hence increases the effective optical resolution by this factor. To overcome the current limits of these complementary approaches, we combined ExM with STED (ExSTED) and demonstrated an increase in resolution of up to 30-fold compared to conventional microscopy (<10 nm lateral and ∼50 nm isotropic). While the increase in resolution is straightforward, we found that high-fidelity labeling via multi-epitopes is required to obtain emitter densities that allow ultrastructural details with ExSTED to be resolved. Our work provides a robust template for super-resolution microscopy of entire cells in the ten nanometer range.

Changes in microtubule overlap length regulate kinesin-14-driven microtubule sliding.

Microtubule-crosslinking motor proteins, which slide antiparallel microtubules, are required for the remodeling of microtubule networks. Hitherto, all microtubule-crosslinking motors have been shown to slide microtubules at a constant velocity until no overlap remains between them, leading to the breakdown of the initial microtubule geometry. Here, we show in vitro that the sliding velocity of microtubules, driven by human kinesin-14 HSET, decreases when microtubules start to slide apart, resulting in the maintenance of finite-length microtubule overlaps. We quantitatively explain this feedback using the local interaction kinetics of HSET with overlapping microtubules that cause retention of HSET in shortening overlaps. Consequently, the increased HSET density in the overlaps leads to a density-dependent decrease in sliding velocity and the generation of an entropic force that antagonizes the force exerted by the motors. Our results demonstrate that a spatial arrangement of microtubules can regulate the collective action of molecular motors through the local alteration of their individual interaction kinetics.

Biological activity of a nanofibrous barrier membrane containing bone morphogenetic protein formed by core-shell electrospinning as a sustained delivery vehicle.

This study reports the in vitro and in vivo biological activities of recombinant human bone morphogenetic protein 2 (rhBMP-2) released from the core-shell structure of a nanofibrous barrier membrane as a sustained delivery model for bone regeneration. RhBMP-2 incorporating poly(ethylene glycol) was used as the core, and poly(caprolactone) was used as the shell surrounding the core. To determine its release profiles, the release solution was collected and the amount of rhBMP-2 was measured by ELlSA at different time points. In vitro rhBMP-2, released from the delivery system over at least 24 days, reached a stable rate of 500 pg per day and guided bone marrow mesenchymal stem cells (BMMSCs) to express osteogenic genes. The distribution and proliferation of BMMSCs in the nanofibrous barrier membrane was measured by laser confocal scanning microscopy (LCSM) and scanning electron microscopy (SEM). The biological activity of rhBMP-2 was tested in BMMSC/membrane culture in vitro and in a rabbit calvarium defect model in vivo. Osteogenic genes osteonectin (ON) and core binding factor-α1 (Cbf-α1) expression of the BMMSCs cultured on the BMP-2-PEG/PCL membrane were significantly higher than those of cells on the PEG/PCL membrane at the late time points using real-time PCR (p < 0.05). The membranes containing the rhBMP-2 group exhibited the fastest and most bone formation compared to others in rabbit cranial defect models (p < 0.05). This study revealed that rhBMP-2 could be incorporated into a core-shell electrospun membrane, and preserve sustained release capability and biological activity.