Development of an enhanced immunoassay based on protein nanoparticles displaying an IgG-binding domain and luciferase.

Detection of small amounts of target molecules with high sensitivity is important for the diagnosis of many diseases, including cancers, and is particularly important to detect early stages of disease. Here, we report the development of a temperature-responsive fusion protein (ELP-DCN) comprised of an elastin-like polypeptide (ELP), poly-aspartic acid (D), antibody-binding domain C (C), and NanoLuc luciferase (N). ELP-DCN proteins form nanoparticles above a certain threshold temperature that display an antibody-binding domain and NanoLuc luciferase on their surface. ELP-DCN nanoparticles can be applied for enhancement of immunoassay systems because they provide more antibody-binding sites and an increased number of luciferase molecules, resulting in an increase in assay signal. Here, we report the detection of human serum albumin (HSA) as a model protein using anti-HSA and ELP-DCN proteins. Upon formation of ELP-DCN nanoparticles, the detection limit improved tenfold compared to the monomeric form of ELP-DCN.

Temperature-Responsive Multifunctional Protein Hydrogels with Elastin-like Polypeptides for 3-D Angiogenesis.

Supramolecular protein hydrogels with tunable properties represent promising candidates for advanced designer extracellular matrices (ECMs). To control cellular functions, ECMs should be able to spatiotemporally regulate synergistic signaling between transmembrane receptors and growth factor (GF) receptors. In this study, we developed genetically engineered temperature-responsive multifunctional protein hydrogels. The designed hydrogel was fabricated by combining the following four peptide blocks: thermosensitive elastin-like polypeptides (ELPs), a polyaspartic acid (polyD) chain to control aggregation and delivery of GFs, a de novo-designed helix peptide that forms antiparallel homotetrameric coiled-coils, and a biofunctional peptide. The resultant coiled-coil unit bound ELPs (CUBEs) exhibit a controllable sol-gel transition with tunable mechanical properties. CUBEs were functionalized with bone sialoprotein-derived RGD (bRGD), and human umbilical vein endothelial cells (HUVECs) were three-dimensionally cultured in bRGD-modified CUBE (bRGD-CUBE) hydrogels. Proangiogenic activity of HUVECs was promoted by bRGD. Moreover, heparin-binding angiogenic GFs were immobilized to bRGD-CUBEs via electrostatic interactions. HUVECs cultured in GF-tethered bRGD-CUBE hydrogels formed three-dimensional (3-D) tubulelike structures. The designed CUBE hydrogels may demonstrate utility as advanced smart biomaterials for biomedical applications. Further, the protein hydrogel design strategy may provide a novel platform for constructing designer 3-D microenvironments for specific cell types.

Construction of DNA-displaying nanoparticles by enzymatic conjugation of DNA and elastin-like polypeptides using a replication initiation protein.

DNA-displaying nanoparticles comprised of conjugates of single-stranded DNA (ssDNA) and elastin-like polypeptide (ELP) were developed. ssDNA was enzymatically conjugated to ELPs via a catalytic domain of Porcine Circovirus type 2 replication initiation protein (pRep) fused to ELPs. Nanoparticles were formed upon heating to temperatures above the phase transition temperature due to the hydrophobicity of ELPs and the hydrophilicity of conjugated ssDNA. We demonstrated the applicability of the resultant nanoparticles as drug carriers with tumor-targeting properties by conjugating a DNA aptamer, which is known to bind to Mucin 1 (MUC1), to ELPs. DNA aptamer-displaying nanoparticles encapsulating the anti-cancer drug paclitaxel were able to bind to cells overexpressing MUC1 and induce cell death.

Development of drug-loaded protein nanoparticles displaying enzymatically-conjugated DNA aptamers for cancer cell targeting.

Modification of protein-based drug carriers with tumor-targeting properties is an important area of research in the field of anticancer drug delivery. To this end, we developed nanoparticles comprised of elastin-like polypeptides (ELPs) with fused poly-aspartic acid chains (ELP-D) displaying DNA aptamers. DNA aptamers were enzymatically conjugated to the surface of the nanoparticles via genetic incorporation of Gene A* protein into the sequence of the ELP-D fusion protein. Gene A* protein, derived from bacteriophage ϕX174, can form covalent complexes with single-stranded DNA via the latter's recognition sequence. Gene A* protein-displaying nanoparticles exhibited the ability to deliver the anticancer drug paclitaxel (PTX), whilst retaining activity of the conjugated Gene A* protein. PTX-loaded protein nanoparticles displaying DNA aptamers known to bind to the MUC1 tumor marker resulted in increased cytotoxicity with MCF-7 breast cancer cells compared to PTX-loaded protein nanoparticles without the DNA aptamer modification.

Construction of DNA-NanoLuc luciferase conjugates for DNA aptamer-based sandwich assay using Rep protein.

OBJECTIVE: We developed a DNA-NanoLuc luciferase (NnaoLuc) conjugates for DNA aptamer-based sandwich assay using the catalytic domain of the replication initiator protein derived from porcine circovirus type 2 (pRep). RESULTS: For construction of DNA aptamer and NanoLuc conjugate using the catalytic domain of Rep from PCV2. pRep fused to NanoLuc was genetically constructed and expressed in E. coli. After purification, the activities of fused pRep and NanoLuc were evaluated, and DNA-NanoLuc conjugates were constructed via the fused pRep. Finally, constructed DNA-NanoLuc conjugates were applied for use in a DNA aptamer-based sandwich assay. Here, pRep was used not only for conjugation of the NanoLuc to the detection aptamer, but also for immobilization of the capture aptamer on the plate surface. CONCLUSION: We have demonstrated that DNA-NanoLuc conjugates via the catalytic domain of PCV2 Rep could be applied for DNA aptamer-based sandwich assay system.

Application of elastin-based nanoparticles displaying antibody binding domains for a homogeneous immunoassay.

Nanoparticles are small size-controlled particles from 1 to 100 nm diameters and characterized by their structure, base material and functional units displayed on their surfaces. In this study, protein-based nanoparticles composed of a hydrophobic elastin-like peptide unit, a hydrophilic aspartic acid-rich peptide unit and displaying antibody binding domains on their surfaces, were designed and genetically synthesized. The constituent fusion proteins, termed ELP-D-C, were found to exist in monomeric form (ELP-D-C/monomer) at low temperature. Above the phase transition temperature, however, ELP-D-C was found to rapidly self-assemble to form spherical micelles (ELP-D-C/micelle) with a hydrophobic core and diameters of ∼40 nm. Furthermore, ELP-D-C/micelle were shown to display antibody binding domains on their surfaces, which allowed for immobilization of antibodies and subsequent formation of large, visually detectable complexes in the presence of target molecule (antigen), whose sizes increased in proportion to the target molecule concentration. The observed target molecule concentration-dependent complex formation suggests that ELP-D-C/micelle may be useful as base particles in applications such as homogeneous turbidity immunoassays.

A DNA-scaffold platform enhances a multi-enzymatic cycling reaction.

OBJECTIVE: We explored the co-localization of multiple enzymes on a DNA backbone via a DNA-binding protein, Gene-A* (A*-tag) to increase the efficiency of cascade enzymatic reactions. RESULTS: Firefly luciferase (FLuc) and pyruvate orthophosphate dikinase (PPDK) were genetically fused with A*-tag and modified with single-stranded (ss) DNA via A*-tag. The components were assembled on ssDNA by hybridization, thereby enhancing the efficiency of the cascading bioluminescent reaction producing light emission from pyrophosphate. The activity of A*-tag in each enzyme was investigated with dye-labeled DNA. Co-localization of the enzymes via hybridization was examined using a gel shift assay. The multi-enzyme complex showed significant improvement in the overall efficiency of the cascading reaction in comparison to a mixture of free enzymes. CONCLUSION: A*-tag is highly convenient for ssDNA modification of versatile enzymes, and it can be used for construction of functional DNA-enzyme complexes.

Fluorescent and luminescent fusion proteins for analyses of amyloid beta peptide aggregation.

The amyloid beta (Aß) peptide is regarded as a causative agent of Alzheimer's disease. In this study, fluorescent and luminescent fusion proteins were constructed to analyze Aß aggregation. A system was developed to monitor changes in luminescence that provides information about Aß aggregation. In the presence of monomeric Aß, the fusion protein exhibits higher luminescence intensity, and the luminescence intensity is diminished after aggregation of the fusion protein and Aß. In contrast, the fluorescence is sustained in the presence of Aß. In the absence of Aß, the fusion protein self-aggregates, and its luminescence and fluorescence are quenched, thus decreasing the background fluorescence and enhancing the detection of Aß inside and outside the cells. The ratio of the luminescence intensity to the fluorescence intensity would allow the aggregation degrees of Aß to be distinguished. This study would be a promising method for analyzing the aggregation state of a particular amyloid protein/peptide (monomer, oligomer, or fibril), as well as the distribution of the amyloid protein/peptide within and at the cell surface, by using a single fusion protein. Copyright © 2017 European Peptide Society and John Wiley & Sons, Ltd.

Development of a Split SNAP-CLIP Double Labeling System for Tracking Proteins Following Dissociation from Protein-Protein Complexes in Living Cells.

The split SNAP-tag protein-fragment complementation assay (PCA) is a useful tool for imaging protein-protein interactions (PPIs) in living cells. In contrast to conventional methods employed for imaging PPIs, the split SNAP-tag PCA enables tracking of proteins following dissociation from protein-protein complexes. A limitation of this system, however, is that it only allows for labeling and tracking of one of the proteins forming the protein-protein complex. To track both proteins forming a protein-protein complex, each protein needs to be appropriately labeled. In this study, a split SNAP-CLIP double labeling system is developed and applied for tracking of each protein forming a protein-protein complex. As a proof-of concept, FM protein for PPIs and protein kinase C alpha (PKCα) for translocation are introduced to a split SNAP-CLIP double labeling system. The results show a split SNAP-CLIP double labeling system enables labeling of both proteins in a protein-protein complex and subsequent tracking of each of the proteins following dissociation from the protein-protein complexes in living cells.

Construction of a Defined Biomimetic Matrix for Long-Term Maintenance of Mouse Induced Pluripotent Stem Cells.

The existing in vitro culture systems often use undefined and animal-derived components for the culture of pluripotent stem cells. Artificial bioengineered peptides have the potential to become alternatives to these components of extracellular matrix (ECM). Integrins and cadherins are two cell adhesion proteins important for stem cell self-renewal, differentiation, and phenotype stability. In the present study, we sought to mimic the physico-biochemical properties of natural ECMs that allow self-renewal of mouse induced pluripotent stem cells (iPSCs). We develop a genetically engineered ECM protein (ERE-CBP) that contains (i) an integrin binding peptide sequence (RGD/R), (ii) an E-/N-cadherin binding peptide sequence (SWELYYPLRANL/CBP), and (iii) 12 repeats of APGVGV elastin-like polypeptides (ELPs/E).While ELPs allow efficient coating by binding to nontreated hydrophobic tissue culture plates, RGD/R and CBP support integrin- and cadherin-dependent cell attachment, respectively. Mouse iPSCs on this composite matrix exhibit a more compact phenotype compared to cells on control gelatin substrate. We also demonstrated that the ERE-CBP supports proliferation and long-term self-renewal of mouse iPSCs for up to 17 passages without GSK3ß (CHIR99021) and Erk (PD0325901) inhibitors. Overall, our engineered ECM protein, which is cost-effective to produce in prokaryotic origin and flexible to modify with other cell adhesion peptides or growth factors, provides a novel approach for expansion of mouse iPSCs in vitro.

Design of luciferase-displaying protein nanoparticles for use as highly sensitive immunoassay detection probes.

In this study, we developed a protein nanoparticle-based immunoassay to detect cancer biomarkers using a bioluminescent fusion protein. This method relies on the use of protein nanoparticles comprised of genetically-engineered elastin-like polypeptides (ELPs) fused with poly-aspartic acid tails (ELP-D), previously developed in our lab. The sizes of the self-assembled ELP-D nanoparticles can be regulated at the nanoscale by charged repulsion of the poly-aspartic acid chains. To improve the sensitivity of enzyme-linked immunosorbent assays (ELISAs), we herein demonstrate the multivalent display of NanoLuc® (Nluc) luciferase and a biotin acceptor peptide (BAP) on the surfaces of ELP-D nanoparticles, and demonstrate the sensitivity of these multivalent nanoparticles as detection probes. The fusion protein comprised of ELP-D and Nluc-BAP (ELP-D-Nluc-BAP) was found to form nanoparticles with Nluc and BAP displayed multivalently on their surfaces. Moreover, the use of the nanoparticles in ELISA resulted in a detection sensitivity for α-fetoprotein (AFP) about 10 times higher than that of an assay relying on the use of the monomeric version of the fusion protein. Taken together, ELP-D-based nanoparticles displaying multivalent luciferases on their surfaces enable the construction of an ELISA with enhanced sensitivity.

Growth Factor Tethering to Protein Nanoparticles via Coiled-Coil Formation for Targeted Drug Delivery.

Protein-based nanoparticles are attractive carriers for drug delivery because they are biodegradable and can be genetically designed. Moreover, modification of protein-based nanoparticles with cell-specific ligands allows for active targeting abilities. Previously, we developed protein nanoparticles comprising genetically engineered elastin-like polypeptides (ELPs) with fused polyaspartic acid tails (ELP-D). Epidermal growth factor (EGF) was displayed on the surface of the ELP-D nanoparticles via genetic design to allow for active cell-targeting abilities. Herein, we focused on the coiled-coil structural motif as a means for noncovalent tethering of growth factor to ELP-D. Specifically, two peptides known to form a heterodimer via a coiled-coil structural motif were fused to ELP-D and single-chain vascular endothelial growth factor (scVEGF121), to facilitate noncovalent tethering upon formation of the heterodimer coiled-coil structure. Drug-loaded growth factor-tethered ELP-Ds were found to be effective against cancer cells by provoking cell apoptosis. These results demonstrate that tethering growth factor to protein nanoparticles through coiled-coil formation yields a promising biomaterial candidate for targeted drug delivery.

Tracking a protein following dissociation from a protein-protein complex using a split SNAP-tag system.

Protein-protein interactions (PPIs) are important for various biological processes in living cells. Several methods have been developed for the visualization of PPIs in vivo; however, these methods are unsuitable for visualization of post-PPI events such as dissociation and translocation. In this study, we applied a split SNAP-tag system for the visualization of post-PPI events. This method enabled tracking of the protein following dissociation from the protein-protein complex. Thus, the split SNAP-tag system should prove to be a useful tool for visualization of post-PPI events.

Assembly of zinc finger motif-fused enzymes on a dsDNA scaffold for catalyzing consecutive reactions with a proximity effect.

The feasibility of assembling enzymes, catalyzing consecutive reactions, on to a double-stranded DNA (dsDNA) scaffold utilizing zinc finger motifs is described. The catalytic activities of two zinc finger motif-fused enzymes catalyzing a bioluminescence reaction with energy recycling, namely pyruvate phosphate dikinase and firefly luciferase, have been evaluated. Bioluminescence measurements with dsDNA scaffolds coding a different distance between the binding sites for each zinc finger motif-fused enzyme confirmed the effect of the distance, proving the proximity effect of ATP recycling presumed to be the result of efficient intermediate diffusion. Thus, fusion to zinc finger motifs offers a promising option for the assembly of bi-enzymes, catalyzing a consecutive reaction, onto a dsDNA scaffold with a proximity effect.

Cellular differentiation assessments by measuring the degree of cellular internalization and membrane adsorption using designed peptides.

We demonstrate examples of cellular differentiation assessments, including cellular neurite outgrowth and fat cell maturation, by measuring the degree of membrane adsorption or cellular internalization using designed peptides. Because changes in the cellular membrane and cytosol during differentiation were shown to influence membrane adsorption and cellular internalization, we could successfully evaluate the extent of differentiation simply like stain indicators.

Systematic screening of the cellular uptake of designed alpha-helix peptides.

The cellular penetration (CP) activity of functional molecules has attracted significant attention as one of the most promising new approaches for drug delivery. In particular, cell-penetrating peptides (CPPs) have been studied extensively in cellular engineering. Because there have been few large-scale systematic studies to identify peptide sequences with optimal CP activity or that are suitable for further applications in cell engineering, such as cell-specific penetration and cell-selective culture, we screened and compared the cellular uptake (CU) activity of 54 systematically designed α-helical peptides in HeLa cells. Furthermore, the CU activity of 24 designed peptides was examined in four cell lines using a cell fingerprinting technique and statistical approaches. The CU activities in various cells depended on amino acid residues of peptide sequences as well as charge, α-helical content and hydrophobicity of the peptides. Notably, the mutation of a single residue significantly altered the CU ability of a peptide, highlighting the variability of cell uptake mechanisms. Moreover, these results demonstrated the feasibility of cell-selective culture by conducting cell-selective permeation and death in cultures containing two cell types. These studies may lead to further peptide library design and screening for new classes of CPPs with useful functions.

Development of a specific siRNA delivery system into HeLa cells using an IgG-binding fusion protein.

Stable carriers are required for delivering siRNA to cells. The use of polyethyleneimine (PEI) as gene carrier has been researched extensively; however, it does not provide sufficient protection from RNase degradation and is not suitable for targeted siRNA delivery to specific cells. In this study, two repeats of Fc binding domain of protein G (C2) were used to introduce a specific antibody to PEI-based carrier of siRNA. In addition, we used the double-stranded RNA binding domain (DRBD) that can bind to siRNA. The complex, consisting of PEI, siRNA and constructed fusion protein, TrxC2DRBD including C2 and DRBD domains, could protect siRNA from RNase degradation. Furthermore, cell specific siRNA delivery into HeLa cells could be performed by the complex fusion with specific antibodies via C2 domain.

Sensitive Detection of Tumor Cells Using Protein Nanoparticles with Multiple Displays of DNA Aptamers and Bioluminescent Reporters.

Simple and effective detection methods for circulating tumor cells are essential for early detection and progression monitoring of tumors. The use of DNA aptamer and bioluminescence is expected to be a key tool for the simple, effective, and sensitive detection of tumor cells. Herein, we designed multifunctional protein nanoparticles for the detection of tumor cells using DNA aptamer and bioluminescence. Fusion proteins (ELP-poly(d)-POIs), composed of elastin-like polypeptide (ELP) fused with protein of interests (POIs) via poly(aspartic acid) (poly(d)), formed the protein nanoparticles based on the temperature responsivity of ELP sequences, leading to multiply displayed POIs on the protein nanoparticles. In the present study, we focused on porcine circovirus type 2 replication initiation protein (Rep), which covalently conjugated with DNA aptamers, and NanoLuc luciferase (Nluc), which emitted a strong bioluminescence, as POIs. ELP-poly(d)-Rep and ELP-poly(d)-Nluc were constructed and formed the protein nanoparticles with multiply displayed Nluc and Rep (DNA aptamer) that amplified the bioluminescence signal and tumor recognition ability. Mucin-1 (MUC1)-overexpressing human breast tumor MCF7 cells and MUC1-recognizing aptamer (MUC1 aptamer) were selected as models. The MUC1 aptamer-conjugated protein nanoparticles exhibited a 13.7-fold higher bioluminescence signal to MCF-7 cells than to human embryonic kidney 293 (HEK293) cells, which express low levels of MUC1. Furthermore, the protein nanoparticles could detect up to 70.7 cells/mL of MCF-7 cells from a cell suspension containing HEK-293. The protein nanoparticles with multiple Rep and Nluc show a great potential as a material for detecting CTCs.

Detection of antigens using a protein-DNA chimera developed by enzymatic covalent bonding with phiX gene A*.

The chemical reactions used to make antibody-DNA conjugates in many immunoassays diminish antigen-binding activity and yield heterogeneous products. Here, we address these issues by developing an antibody-based rolling circle amplification (RCA) strategy using a fusion of φX174 gene A* protein and Z(mab25) (A*-Zmab). The φX174 gene A* protein is an enzyme that can covalently link with DNA, while the Z(mab25) protein moiety can bind to specific species of antibodies. The DNA in an A*-Zmab conjugate was attached to the A* protein at a site chosen to not interfere with protein function, as determined by enzyme-linked immunosorbent assay (ELISA) and gel mobility shift analysis. The novel A*-Zmab-DNA conjugate retained its binding capabilities to a specific class of murine immunoglobulin γ1 (IgG1) but not to rabbit IgG. This indicates the generality of the A*-Zmab-based immuno-RCA assay that can be used in-sandwich ELISA format. Moreover, the enzymatic covalent method dramatically increased the yields of A*-Zmab-DNA conjugates up to 80% after a 15 min reaction. Finally, sensitive detection of human interferon-γ (IFN-γ) was achieved by immuno-RCA using our fusion protein in sandwich ELISA format. This new approach of the use of site-specific enzymatic DNA conjugation to proteins should be applicable to fabrication of novel immunoassays for biosensing.

Induction of motor neuron differentiation by transduction of Olig2 protein.

Olig2 protein, a member of the basic helix-loop-helix transcription factor family, was introduced into the mouse embryonic carcinoma cell line P19 for induction of motor neuron differentiation. We show that Olig2 protein has the ability to permeate the cell membrane without the addition of a protein transduction domain (PTD), similar to other basic helix-loop-helix transcription factors such as MyoD and NeuroD2. Motor neuron differentiation was evaluated for the elongation of neurites and the expression of choline acetyltransferase (ChAT) mRNA, a differentiation marker of motor neurons. By addition of Olig2 protein, motor neuron differentiation was induced in P19 cells.