Cellular internalization of arginine‐rich peptides into tobacco suspension cells: a structure–activity relationship study

Translocation of several fluorescently labeled arginine‐rich peptides into intact plant cells was quantitatively examined in order to investigate the structural factors required for efficient cellular internalization, and thereby, to evaluate the potential of arginine‐rich peptides as intracellular delivery vectors in plants. Cell‐penetrating peptides (CPPs) such as arginine‐rich peptides permit the direct introduction of biologically active macromolecules into plant cytoplasm to manipulate various intracellular processes. While a significant level of adsorption of applied arginine‐rich peptides was observed in the cell walls rich in negative charges, removal of adsorbed peptides by trypsin treatment allowed determination of the amount of internalized peptides in a quantitative manner using spectrofluorometric analysis. The internalization of arginine‐rich peptides depended on the number of arginine residues, and the peptide containing eight arginine residues showed most effective internalization. Besides, the position of small cargoes attached to the arginine‐rich peptides markedly affected the internalization efficiency. The results obtained in this study provide useful information for the development of efficient intracellular delivery tools in plant science. Copyright © 2008 European Peptide Society and John Wiley & Sons, Ltd.     

Tandem Cell‐Free Protein Synthesis as a Tool for Rapid Screening of Optimal Molecular Chaperones

A simple and flexible method is developed for rapid screening of molecular chaperones that enhance the functional expression of recombinant proteins. A panel of molecular chaperones are transiently expressed in a reaction mixture of cell‐free protein synthesis and then a target protein is subsequently expressed in the presence of these presynthesized molecular chaperones. The biological activity of the cell‐free synthesized target protein is compared to identify the effective molecular chaperones. This strategy successfully identifies individual and combinations of bacterial molecular chaperones that markedly improved the functional expression of horseradish peroxidase. The authors believe that the presented strategy provides a versatile platform for the optimal production of functional proteins, and can also be extended to studies of other interacting proteins.     

Combinatorial, selective and reversible control of gene expression using oligodeoxynucleotides in a cell-free protein synthesis system

Herein we describe the methods for selective and reversible regulation of gene expression using antisense oligodeoxynucleotides (ODNs) in a cell-free protein synthesis system programmed with multiple DNAs. Either a complete shut down or controlled level of gene expression was attained through the antisense ODN-mediated regulation of mRNA stability in the reaction mixture. In addition to the primary control of gene expression, we also demonstrate that the inhibition of protein synthesis can be reversed by using an anti-antisense ODN sequence that strips the antisense ODN off the target sequence of mRNA. As a result, sequential additions of the antisense and anti-antisense ODNs enabled the stop-and-go expression of protein molecules. Through the on-demand regulation of gene expression, presented results will provide a versatile platform for the analysis and understanding of the complicated networks of biological components.     

Predicting binding modes of reversible peptide‐based inhibitors of falcipain‐2 consistent with structure–activity relationships

Falcipain‐2 (FP‐2) is a major hemoglobinase of Plasmodium falciparum, considered an important drug target for the development of antimalarials. A previous study reported a novel series of 20 reversible peptide‐based inhibitors of FP‐2. However, the lack of tridimensional structures of the complexes hinders further optimization strategies to enhance the inhibitory activity of the compounds. Here we report the prediction of the binding modes of the aforementioned inhibitors to FP‐2. A computational approach combining previous knowledge on the determinants of binding to the enzyme, docking, and postdocking refinement steps, is employed. The latter steps comprise molecular dynamics simulations and free energy calculations. Remarkably, this approach leads to the identification of near‐native ligand conformations when applied to a validation set of protein‐ligand structures. Overall, we proposed substrate‐like binding modes of the studied compounds fulfilling the structural requirements for FP‐2 binding and yielding free energy values that correlated well with the experimental data. Proteins 2017; 85:1666–1683. © 2017 Wiley Periodicals, Inc.     

Study on the synthesis and structure–effect relationship of multi‐aryl imidazoles with their fluorescence properties

In this paper, 23 multi‐aryl imidazole derivatives were synthesized and identified by nuclear magnetic resonance, ultraviolet‐visible and elemental analysis. At the same time, their ultraviolet‐visible maximum absorption (λ_ab^max), fluorescence emission maximum (λ_em^max) and quantum yields (Ф_f) were measured. The relationships between the optical behaviors and structures for these compounds were assessed. The results show that the λ^max_ab and λ^max_em are red‐shifted and the fluorescence Ф_f are increased by the introduction of electron‐withdrawing substituents and the increase in the planarity of multi‐aryl imidazole molecules. The results also showed that the fluorescence quantum yields of the compounds containing two imidazole nuclei are double the corresponding mono‐imidazole nucleus compounds. Copyright © 2013 John Wiley & Sons, Ltd.     

Advances in Cell‐Free Biosensors: Principle,Mechanism, and Applications

Synthetic biology has promoted the development of biosensors as tools for detecting trace substances. In the past, biosensors based on synthetic biology have been designed on living cells, but the development of cell biosensors has been greatly limited by defects such as genetically modified organism problem and the obstruction of cell membrane. However, the advent of cell‐free synthetic biology addresses these limitations. Biosensors based on the cell‐free protein synthesis system have the advantages of higher safety, higher sensitivity, and faster response time over cell biosensors, which make cell‐free biosensors have a broader application prospect. This review summarizes the workflow of various cell‐free biosensors, including the identification of analytes and signal output. The detection range of cell‐free biosensors is greatly enlarged by different recognition mechanisms and output methods. In addition, the review also discusses the applications of cell‐free biosensors in environmental monitoring and health diagnosis, as well as existing deficiencies and aspects that should be improved. In the future, through continuous improvement and optimization, the potential of cell‐free biosensors will be stimulated, and their application fields will be expanded.     

Production of G protein‐coupled receptors in an insect‐based cell‐free system

The biochemical analysis of human cell membrane proteins remains a challenging task due to the difficulties in producing sufficient quantities of functional protein. G protein‐coupled receptors (GPCRs) represent a main class of membrane proteins and drug targets, which are responsible for a huge number of signaling processes regulating various physiological functions in living cells. To circumvent the current bottlenecks in GPCR studies, we propose the synthesis of GPCRs in eukaryotic cell‐free systems based on extracts generated from insect (Sf21) cells. Insect cell lysates harbor the fully active translational and translocational machinery allowing posttranslational modifications, such as glycosylation and phosphorylation of de novo synthesized proteins. Here, we demonstrate the production of several GPCRs in a eukaryotic cell‐free system, performed within a short time and in a cost‐effective manner. We were able to synthesize a variety of GPCRs ranging from 40 to 133 kDa in an insect‐based cell‐free system. Moreover, we have chosen the μ opioid receptor (MOR) as a model protein to analyze the ligand binding affinities of cell‐free synthesized MOR in comparison to MOR expressed in a human cell line by “one‐point” radioligand binding experiments. Biotechnol. Bioeng. 2017;114: 2328–2338. © 2017 The Authors. Biotechnology and Bioengineering Published by Wiley Periodicals, Inc.     

Cell‐free production of a therapeutic protein: Expression,purification, and characterization of recombinant streptokinase using a CHO lysate

The use of cell‐free systems to produce recombinant proteins has grown rapidly over the past decade. In particular, cell‐free protein synthesis (CFPS) systems based on mammalian cells provide alternative methods for the production of many proteins, including those that contain disulfide bonds, glycosylation, and complex structures such as monoclonal antibodies. In the present study, we show robust production of turbo green fluorescent protein (tGFP) and streptokinase in a cell‐free system using instrumented mini‐bioreactors for highly reproducible protein production. We achieved recombinant protein production (～600 μg/ml of tGFP and 500 μg/ml streptokinase) in 2.5 hr of expression time, comparable to previously reported yields for cell‐free protein expression. Also, we demonstrate the use of two different affinity tags for product capture and compare those to a tag‐free self‐cleaving intein capture technology. The intein purification method provided a product recovery of 86%, compared with 52% for conventionally tagged proteins, while resulting in a 30% increase in total units of activity of purified recombinant streptokinase compared with conventionally tagged proteins. These promising beneficial features combined with the intein technology makes feasible the development of dose‐level production of therapeutic proteins at the point‐of‐care.     

Creating a completely “cell‐free” system for protein synthesis

Cell‐free protein synthesis is a promising tool to take biotechnology outside of the cell. A cell‐free approach provides distinct advantages over in vivo systems including open access to the reaction environment and direct control over all chemical components for facile optimization and synthetic biology integration. Promising applications of cell‐free systems include portable diagnostics, biotherapeutics expression, rational protein engineering, and biocatalyst production. The highest yielding and most economical cell‐free systems use an extract composed of the soluble component of lysed Escherichia coli. Although E. coli lysis can be highly efficient (>99.999%), one persistent challenge is that the extract remains contaminated with up to millions of cells per mL. In this work, we examine the potential of multiple decontamination strategies to further reduce or eliminate bacteria in cell‐free systems. Two strategies, sterile filtration and lyophilization, effectively eliminate contaminating cells while maintaining the systems’ protein synthesis capabilities. Lyophilization provides the additional benefit of long‐term stability at storage above freezing. Technologies for personalized, portable medicine and diagnostics can be expanded based on these foundational sterilized and completely “cell‐free” systems. © 2015 American Institute of Chemical Engineers Biotechnol. Prog., 31:1716–1719, 2015     

Toward cell‐free biofuel production: Stable immobilization of oligomeric enzymes

To overcome the main challenges facing alcohol‐based biofuel production, we propose an alternate simplified biofuel production scheme based on a cell‐free immobilized enzyme system. In this paper, we measured the activity of two tetrameric enzymes, a control enzyme with a colorimetric assay, β‐galactosidase, and an alcohol‐producing enzyme, alcohol dehydrogenase, immobilized on multiple surface curvatures and chemistries. Several solid supports including silica nanoparticles (convex), mesopourous silica (concave), diatomaceous earth (concave), and methacrylate (concave) were examined. High conversion rates and low protein leaching was achieved by covalent immobilization of both enzymes on methacrylate resin. Alcohol dehydrogenase (ADH) exhibited long‐term stability and over 80% conversion of aldehyde to alcohol over 16 days of batch cycles. The complete reaction scheme for the conversion of acid to aldehyde to alcohol was demonstrated in vitro by immobilizing ADH with keto‐acid decarboxylase free in solution. © 2014 American Institute of Chemical Engineers Biotechnol. Prog., 30:324–331, 2014     

Efficient tRNA degradation and quantification in Escherichia coli cell extract using RNase‐coated magnetic beads: A key step toward codon emancipation

Emancipating sense codons toward a minimized genetic code is of significant interest to science and engineering. A key approach toward sense codon emancipation is the targeted in vitro removal of native tRNA. However, challenges remain such as the insufficient depletion of tRNA in lysate‐based in vitro systems and the high cost of the purified components system (PURE). Here we used RNase‐coated superparamagnetic beads to efficiently degrade E. coli endogenous tRNA. The presented method removes >99% of tRNA in cell lysates, while partially preserving cell‐free protein synthesis activity. The resulting tRNA‐depleted lysate is compatible with in vitro‐transcribed synthetic tRNA for the production of peptides and proteins. Additionally, we directly measured residual tRNA using quantitative real‐time PCR. © 2017 American Institute of Chemical Engineers Biotechnol. Prog., 33:1401–1407, 2017     

Regulation by competition: a hidden layer of gene regulatory network

Background: Molecular competition brings about trade-offs of shared limited resources among the cellular components, and thus introduces a hidden layer of regulatory mechanism by connecting components even without direct physical interactions. Several molecular competition scenarios have been observed recently, but there is still a lack of systematic quantitative understanding to reveal the essence of molecular competition. Methods: Here, by abstracting the analogous competition mechanism behind diverse molecular systems, we built a unified coarse-grained competition motif model to systematically integrate experimental evidences in these processes and analyzed general properties shared behind them from steady-state behavior to dynamic responses. Results: We could predict in what molecular environments competition would reveal threshold behavior or display a negative linear dependence. We quantified how competition can shape regulator-target dose-response curve, modulate dynamic response speed, control target expression noise, and introduce correlated fluctuations between targets. Conclusions: This work uncovered the complexity and generality of molecular competition effect as a hidden layer of gene regulatory network, and therefore provided a unified insight and a theoretical framework to understand and employ competition in both natural and synthetic systems.