Optimization of Flow Imaging Microscopy Setting Using Spherical Beads with Optical Properties Similar to Those of Biopharmaceuticals.

Flow imaging microscopy (FIM) is widely used to characterize biopharmaceutical subvisible particles (SVPs). The segmentation threshold, which defines the boundary between the particle and the background based on pixel intensity, should be properly set for accurate SVP quantification. However, segmentation thresholds are often subjectively and empirically set, potentially leading to variations in measurements across instruments and operators. In the present study, we developed an objective method to optimize the FIM segmentation threshold using poly(methyl methacrylate) (PMMA) beads with a refractive index similar to that of biomolecules. Among several candidate particles that were evaluated, 2.5-µm PMMA beads were the most reliable in size and number, suggesting that the PMMA bead size analyzed by FIM could objectively be used to determine the segmentation threshold for SVP measurements. The PMMA bead concentrations measured by FIM were highly consistent with the indicative concentrations, whereas the PMMA bead size analyzed by FIM decreased with increasing segmentation threshold. The optimal segmentation threshold where the analyzed size was closest to the indicative size differed between an instrument with a black-and-white camera and that with a color camera. Inter-instrument differences in SVP concentrations in acid-stressed recombinant adeno-associated virus (AAV) and protein aggregates were successfully minimized by setting an optimized segmentation threshold specific to the instrument. These results reveal that PMMA beads can aid in determining a more appropriate segmentation threshold to evaluate biopharmaceutical SVPs using FIM.

Potential of the Coordinated Actions of Multiple Protein-Based Micromachines for Medical Applications.

Untethered mobile micromachines hold great promise in the development of effective and minimally invasive therapies. Although diverse medical micromachines for specific applications have been developed over the past few decades, the coordinated action of multiple machines with different functions remains largely unexplored. In this study, we created three types of biocompatible micromachines using proteins and demonstrated the potential of their coordinated action for medical applications. As a proof of concept, we demonstrated neural replacement therapy, in which neuroblastomas were killed by using an anticancer prodrug and the first machine that contains enzymes, enabling the conversion of the prodrug into a cytotoxic drug. Subsequently, a second machine composed of extracellular matrix was placed on the dead cancer cells to provide a suitable environment for cell adhesion, on which embryonic stem (ES) cells and stromal cells that promote neural differentiation of stem cells were attached by using third machines capable of delivering cells to target positions with desired patterns. As a result, neuroblastomas were replaced with novel healthy neurons derived from ES cells by teaming multiple protein-based machines. We believe that this work highlights the potential of heterogeneous machine groups for medical treatment and the utility of highly biocompatible and functional micromachines made from proteins, representing an important step forward in building more sophisticated micromachine-based therapies.

Amyloid conformation-dependent disaggregation in a reconstituted yeast prion system.

Disaggregation of amyloid fibrils is a fundamental biological process required for amyloid propagation. However, due to the lack of experimental systems, the molecular mechanism of how amyloid is disaggregated by cellular factors remains poorly understood. Here, we established a robust in vitro reconstituted system of yeast prion propagation and found that heat-shock protein 104 (Hsp104), Ssa1 and Sis1 chaperones are essential for efficient disaggregation of Sup35 amyloid. Real-time imaging of single-molecule fluorescence coupled with the reconstitution system revealed that amyloid disaggregation is achieved by ordered, timely binding of the chaperones to amyloid. Remarkably, we uncovered two distinct prion strain conformation-dependent modes of disaggregation, fragmentation and dissolution. We characterized distinct chaperone dynamics in each mode and found that transient, repeated binding of Hsp104 to the same site of amyloid results in fragmentation. These findings provide a physical foundation for otherwise puzzling in vivo observations and for therapeutic development for amyloid-associated neurodegenerative diseases.

Chemical-gas Sterilization of External Surface of Polymer-based Prefilled Syringes and Its Effect on Stability of Model Therapeutic Protein.

To reduce the risk of infection during intravitreal injections, the external surface of prefilled syringes (PFSs) must be sterilized. Usually, ethylene oxide (EO) gas or vaporized hydrogen peroxide (VHP) is used for sterilization. More recently, nitrogen dioxide (NO2) gas sterilization has been developed. It is known that gas permeability is approximately zero into glass-PFSs. However, polymer-PFSs (P-PFSs) have relatively high gas permeability. Therefore, there are concerns about the potential impact of external surface sterilization on drug solutions in P-PFSs. In this study, P-PFSs [filled with water for injection (WFI) or human serum albumin (HSA) solution] were externally sterilized using EO, VHP, and NO2 gases. For the WFI-filled syringes, the concentration of each gas that ingressed into the WFI was measured. For the HSA solution-filled syringes, the physical and chemical degradation of HSA molecules by each sterilant gas was quantified. For the EO- or VHP-sterilized syringes, the ingressed EO or hydrogen peroxide (H2O2) molecules were detected in the filled WFI. Additionally, EO-adducted or oxidized HSA molecules were observed in the HSA-filled syringes. In contrast, the NO2-sterilized WFI-filled syringes exhibited essentially immeasurable ingressed NO2, and protein degradation was not detected in HSA-filled syringes.

Sequential Assessment of Multiple Epigenetic Modifications of Cytosine in Whole Genomic DNA by Surface Plasmon Resonance.

Since the discovery of the active DNA demethylation pathway in mammals, numerous efforts have been made to distinguish epigenetic cytosine variants, including 5-methylcytosine (5mC), 5-hydroxymethylcytosine (5hmC), 5-formylcytosine (5fC), and 5-carboxylcytosine (5caC). However, the rapid discrimination of multiple cytosine variants in DNA remains challenging because the conventional assays require time-consuming DNA pretreatments, such as enzymatical digestion and chemical conversion. Here we demonstrated the high-throughput discrimination of four cytosine variants in DNA by using a sequential surface-plasmon-resonance (SPR)-based immunochemical assay. The target DNAs were biotinylated in one step with a bifunctional linker 1 and robustly immobilized on a streptavidin-coated sensor surface to hold them in place during an alkali washing designed to remove residual antibodies. By repeating the injection of antibodies and washing, we achieved a sequential assessment of cytosine variants in identical DNA and identified the yield of in vitro 5mC oxidation in genomic DNA by the ten-eleven translocation 1 (TET1) enzyme. These results demonstrated that our sequential SPR-based immunochemical assay was effective for evaluating multiple epigenetic modifications in a whole genome with a single row operation without time-consuming DNA pretreatments.

Immobilization of DNA on Biosensing Devices with Nitrogen Mustard-Modified Linkers.

Immobilization of DNA is an important step in relation to DNA-based biosensors and bioassays with multiple applications. This unit describes synthesis and applications of novel bifunctional linker molecules containing nitrogen mustard and one of two types of functional groups: cyclic disulfide or biotin. Two ways of immobilizing DNA on a surface are described. With the first method, a bifunctional alkylating linker molecule is first reacted with the target DNA to form alkylated DNA and then immobilized on a specific surface. With the second method, the bifunctional alkylating linker molecule is first attached to the surface, and then the target DNA is immobilized through an alkylating reaction with a nitrogen mustard moiety. We have also achieved immunochemical detection and quantification of 5-methylcytosine in a target DNA immobilized by the above methods. The methods for immobilization of intact DNA using novel bifunctional linker molecules are applicable to a wide range of biological analysis techniques. © 2019 by John Wiley & Sons, Inc.

Development of the Bioluminescent Immunoassay for the Detection of 5-Hydroxymethylcytosine in Dinoflagellate.

Cypridina luciferase is a bioluminescent enzyme that has been used as a reporter either in gene expression reporter assays or in immunoassays accompanied by an antibody. To develop a novel bioluminescent assay for the detection of 5-hydroxymethylcytosine, we first conjugated Cypridina luciferase to the antibody against 5-hydroxymethylcytosine. Next, we performed modifications of guanine bases in the genome DNA samples with 4-azidophenylglyoxal and the biotinylation via the azide-Staudinger ligation, which allowed streptavidin to capture and immobilize the genome DNA samples under mild conditions. The detection of 5-hydroxymethylcytosine in the genome DNA samples was performed with the conjugates between Cypridina luciferase and the reduced antibody, which was also confirmed by a surface plasmon resonance assay with the antibody alone. The results obtained from the bioluminescent assay were in good agreement with that of the surface plasmon resonance assay. We succeeded in the detection of 5hmC in the genome DNA samples from the dinoflagellate Pyrocystis Lunula by using this method.

Immobilization of DNA with nitrogen mustard-biotin conjugate for global epigenetic analysis.

We report the quantitative analysis of 5-methylcytosine, a representative epigenetic modification in genomic DNA, with an enzyme-linked immunosorbent assay (ELISA). We synthesized a novel hetero-bifunctional linker molecule consisting of nitrogen mustard and biotin to capture DNA on the surface of biosensing devices. The molecule can successfully immobilize genomic DNA on a streptavidin coated 96-well microplate, which was then employed for immunochemical epigenetic assessment. We achieved the sensitive and quantitative detection of 5-mC in genomic DNA samples. The CpG methylation ratios obtained from our system for mouse brain and mouse small intestine genomes were 79% and 82%, respectively. These numbers are in good agreement with the previously reported methylation ratio of 75-85%, which was identified by whole genome bisulfite sequencing. Accordingly, the present technology using our novel bifunctional linker molecule provides a fast, easy, and inexpensive method for epigenetic assessment, without the need for any conventional bisulfite treatment, polymerase chain reaction (PCR), or sequencing.

Liquid Droplet of Protein-Polyelectrolyte Complex for High-Concentration Formulations.

The formulation of high-concentration protein solutions is a challenging issue for achieving subcutaneous administration. Previously, we developed a method of precipitation-redissolution using polyelectrolyte as a precipitant to produce protein solutions at high concentrations. However, the redissolution yield of proteins was insufficient. This study aims to optimize the solution conditions for practical applications by combining IgG and poly-l-(glutamic acid) (polyE). A systematic analysis of solution pH and polyE size conditions revealed that an acidic condition favors precipitation, whereas neutral pH values are more effective for the redissolution. We find that the optimal size for polyE ranged from 15,000 to 50,000. This slight modification in the procedure in comparison with previous studies increased the precipitation and redissolution yields to nearly 100%, without irreversible protein denaturation. The fully reversible IgG-polyE complex formed as a droplet structure, which is similar to a condensate of liquid-liquid phase separation. The droplet structure plays an indispensable role in the salt-induced, redissolved state, which is pertinent to the new application that takes advantage of the methods to produce highly concentrated protein solutions.

An alkylating immobilization linker for immunochemical epigenetic assessment.

A bifunctional linker molecule containing nitrogen mustard and a cyclic disulfide group has been developed for the covalent immobilization of intact DNA, which allows quantitative analysis of epigenomic modification in immobilized DNA using SPR-based immune sensing.

Noncovalent PEGylation through Protein-Polyelectrolyte Interaction: Kinetic Experiment and Molecular Dynamics Simulation.

Noncovalent binding of polyethylene glycol (PEG) to a protein surface is a unique protein handling technique to control protein function and stability. A diblock copolymer containing PEG and polyelectrolyte chains (PEGylated polyelectrolyte) is a promising candidate for noncovalent attachment of PEG to a protein surface because of the binding through multiple electrostatic interactions without protein denaturation. To obtain a deeper understanding of protein-polyelectrolyte interaction at the molecular level, we investigated the manner in which cationic PEGylated polyelectrolyte binds to anionic α-amylase in enzyme kinetic experiments and molecular dynamics (MD) simulations. Cationic PEG-block-poly(N,N-dimethylaminoethyl) (PEG-b-PAMA) inhibited the enzyme activity of anionic α-amylase due to binding of PAMA chains. Enzyme kinetics revealed that the inhibition of α-amylase activity by PEG-b-PAMA is noncompetitive inhibition manner. In MD simulations, the PEG-b-PAMA molecule was initially located at six different placements of the x-, y-, and z-axis ±20 Å from the center of α-amylase, which showed that the PEG-b-PAMA nonspecifically bound to the α-amylase surface, corresponding to the noncompetitive inhibition manner that stems from the polymer binding to an enzyme surface other than the active site. In addition, the enzyme activity of α-amylase in the presence of PEG-b-PAMA was not inhibited by increasing the ionic strength, consistent with the MD simulation; i.e., PEG-b-PAMA did not interact with α-amylase in high ionic strength conditions. The results reported in this paper suggest that enzyme inhibition by PEGylated polyelectrolyte can be attributed to the random electrostatic interaction between protein and polyelectrolyte.

Aggregative protein-polyelectrolyte complex for high-concentration formulation of protein drugs.

Aggregative protein-polyelectrolyte complex (PPC) has been proposed as a concentrated state of protein with a great potential for biopharmaceutical application. In this review article, we introduce a unique concentration method of protein formulation using PPC for a dozen types of pharmaceutical antibodies, hormones, and enzymes. Aggregative PPC can be obtained only by mixing poly(amino acid)s with proteins under low salt concentration conditions at an ambient temperature. The aggregative PPC is in a stabilized state against shaking, heating, and oxidation. More importantly, the aggregative PPC can be fully redissolved by the addition of physiological saline without denaturation and activity loss for many proteins. In addition, the general toxicity and pharmacokinetic profiles of the aggregative PPC are identical to those of the control antibody formulation. Thus, the protein formulation produced by aggregative PPC would be applicable for biomedical use as a kind of concentrated-state protein.

Wrap-and-Strip Technology of Protein-Polyelectrolyte Complex for Biomedical Application.

A polyelectrolyte is a polymer composed of repeating units of an electrolyte group that enables reversible complex formation with proteins in aqueous solutions. This review introduces "wrap-and-strip" technology of protein-polyelectrolyte complex (PPC) by noncovalent interaction. Storage: protein is stabilized against physical and chemical stresses. Enrichment: precipitation through PPC can be used as an enrichment method without irreversible unfolding. Catalytic activity switch: a complementary charged pair of polyelectrolytes functions as a reversible enzyme activity switch. Hyperactivation: a specific combination of a polyelectrolyte and substrate enhances enzyme activity by one order of magnitude compared with an enzyme alone. Stabilization: PPC increases protein stability against chemical and physical stresses, such as covalently modified polyethylene glycosylated protein. Simple PPC-based technology can expand the applicable fields of soluble proteins in aqueous solutions.

Stress Tolerance of Antibody-Poly(Amino Acid) Complexes for Improving the Stability of High Concentration Antibody Formulations.

The stabilization of antibodies in aqueous solution against physical stress remains a problematic issue for pharmaceutical applications. Recently, protein-polyelectrolyte complex (PPC) formation using poly(amino acids) was proposed to prepare antibody formulation in a salt-dissociable precipitated state without protein denaturation. Here, we investigated the stabilization effect of PPC of therapeutic antibodies with poly-l-glutamic acid on agitation and thermal stress as forms of mechanical and non-mechanical stress, respectively. The precipitated state of PPC prevented the inactivation and aggregation induced by agitation. Similar results were obtained using the suspension state of PPC, but the stabilizing effects were slightly inferior to those of the PPC precipitate. PPC precipitate and PPC suspension prevented heat-induced inactivation of the antibodies, but showed little effect on heat-induced aggregation. Thus, PPC is a new candidate as a simple storage method for antibodies in aqueous solution, as an alternative state for freeze-drying.

Protein-poly(amino acid) precipitation stabilizes a therapeutic protein l-asparaginase against physicochemical stress.

Long-term storage in aqueous solution has been demanded for the practical application of therapeutic proteins. Recently, a precipitation-redissolution method was proposed to prepare salt-dissociable protein-polyelectrolyte complex (PPC). To elucidate the utility of the complex for storage of proteins, we investigated the stress tolerance of PPC precipitates containing l-asparaginase (ASNase) and poly-l-lysine (polyK). PPC precipitate containing ASNase and polyK was prepared by precipitation-redissolution method. The sample was treated to three types of stress, i.e., heat, shaking, and oxidation. The protein concentration, enzyme activity, and CD spectrum of the supernatants of samples were measured after stressed. PPC precipitate consisting of ASNase and polyK showed tolerance against thermal and shaking stress compared to the native solution. In addition, PPC precipitate protected ASNase from inactivation by oxidation. PPC precipitate of ASNase/polyK complex successfully stabilized ASNase against physicochemical stresses. These results suggest that the PPC precipitate has great potential as a storage method in aqueous solution for unstable proteins.

Feasibility of antibody-poly(glutamic acid) complexes: preparation of high-concentration antibody formulations and their pharmaceutical properties.

Development of high-concentration antibody formulations for subcutaneous administration remains challenging. Recently, a precipitation-redissolution method was proposed to prepare suspensions or precipitates of salt-dissociable protein-poly(amino acid) complexes. To elucidate the utility of this method for protein therapy, we investigated the feasibility of a precipitation-redissolution method using poly(amino acid) for high-concentration antibody formulation. Omalizumab and adalimumab formulations of 150 mg/mL could be prepared using poly-l-glutamic acid (polyE) from low-concentration stock solutions. Enzyme-linked immunosorbent assay, circular dichroism, and size-exclusion chromatography revealed that the formation of antibody-polyE complex and precipitation-redissolution process did not significantly affect the immunoreactivity or secondary structure of the antibodies. The precipitation-redissolution method was less time-consuming and more effective than lyophilization-redissolution, evaporation-redissolution, and ultrafiltration from the viewpoint of final yield. Scalability was confirmed from 400 µL to 1.0 L. The general toxicity and pharmacokinetic profiles of the antibody-polyE complex formulations were similar to those of conventional antibody formulations. These results suggested that the precipitation-redissolution method using poly(amino acid) has great potential as a concentration method for antibody formulation and medicinal use.

Noncovalent PEGylation of L-asparaginase using PEGylated polyelectrolyte.

Noncovalent PEGylation has great potential for stabilization of therapeutic proteins. Here, we demonstrated that the noncovalent PEGylation with a PEGylated polyelectrolyte stabilized a therapeutic protein, l-asparaginase (ASNase). Anionic ASNase and cationic poly(ethylene glycol)-block-poly(N,N-dimethylaminoethyl methacrylate) (PEG-b-PAMA) formed a water-soluble protein-polyelectrolyte complex (PPC) without loss of secondary structure and enzyme activity. PPC with PEG-b-PAMA successfully inhibited the shaking-induced inactivation and aggregation of ASNase as well as protease digestion, corresponding to the behaviors of covalently PEGylated ASNase. Thus, noncovalent PEGylation by PEGylated polyelectrolytes is a new candidate for handling of therapeutic proteins.

Protein-poly(amino acid) complex precipitation for high-concentration protein formulation.

A method for concentration of protein solutions is required for high-dosage protein formulation. Here, we present a precipitation-redissolution method by poly(amino acid) for proteins, including therapeutic enzymes, antibodies, and hormones. The proteins were fully precipitated by the addition of poly-L-lysine or poly-L-glutamic acid at low ionic strength, after which precipitate was dissolved at physiological ionic strength. The activities and secondary structures of redissolved proteins, especially antibodies, were almost identical to the native state. The precipitation-redissolution method is a simple and rapid technique for concentration of protein formulations.

Enzyme hyperactivation system based on a complementary charged pair of polyelectrolytes and substrates.

Artificial enzyme activators are of great interest for enzyme applications in a wide range of research fields. Here, we report an enzyme hyperactivation system using polyelectrolytes that are complementary to charged substrates. The enzyme activity of α-chymotrypsin (ChT) for a cationic substrate increased 7-fold at pH 7.0 in the presence of anionic poly(acrylic acid) (PAAc) and for an anionic substrate increased 18-fold at pH 7.0 in the presence of cationic poly(allylamine) (PAA). Analysis of salt and pH effects, enzyme kinetics, dynamic light scattering (DLS), and circular dichroism (CD) indicated that the enzyme activation results from favorable electrostatic interactions between oppositely charged substrates and polyelectrolytes surrounding the enzymes. This hyperactivation system does not require laborious mutagenesis or chemical modification of enzymes and thus is relevant to a number of applications.

Improved complementary polymer pair system: switching for enzyme activity by PEGylated polymers.

The development of technology for on/off switching of enzyme activity is expected to expand the applications of enzyme in a wide range of research fields. We have previously developed a complementary polymer pair system (CPPS) that enables the activity of several enzymes to be controlled by a pair of oppositely charged polymers. However, it failed to control the activity of large and unstable α-amylase because the aggregation of the complex between anionic α-amylase and cationic poly(allylamine) (PAA) induced irreversible denaturation of the enzyme. To address this issue, we herein designed and synthesized a cationic copolymer with a poly(ethylene glycol) backbone, poly(N,N-diethylaminoethyl methacrylate)-block-poly(ethylene glycol) (PEAMA-b-PEG). In contrast to PAA, α-amylase and ß-galactosidase were inactivated by PEAMA-b-PEG with the formation of soluble complexes. The enzyme/PEAMA-b-PEG complexes were then successfully recovered from the complex by the addition of anionic poly(acrylic acid) (PAAc). Thus, dispersion of the complex by PEG segment in PEAMA-b-PEG clearly plays a crucial role for regulating the activities of these enzymes, suggesting that PEGylated charged polymer is a new candidate for CPPS for large and unstable enzymes.