Eiry Kobatake

Detection of local ATP release from activated platelets using cell surface-attached firefly luciferase

We have developed a method for measuring the local concentration of ATP at the extracellular surface of live cells. This method relies on the specific attachment to the cell surface of a chimeric protein that consists of the IgG-binding domain of Staphylococcus aureus protein A fused in-frame with the complete sequence for firefly luciferase (proA-luc). Expression of proA-luc in Escherichia coli and its one-step affinity purification are straightforward. Attachment to cells is demonstrated to be specific and antibody dependent using several suspended and adherent cell types. Light production by cell surface-attached luciferase is continuous, linearly related to ATP concentration, and sufficient to provide nanomolar sensitivity. The spatial resolution of this method enables the observation of strictly local changes in extracellular ATP during its secretion from activated platelets. Furthermore, the activity of cell-attached luciferase is relatively refractory to the inclusion of nucleotidases in the medium, arguing for its effectiveness in cell systems possessing potent ecto-ATPases.We have developed a method for measuring the local concentration of ATP at the extracellular surface of live cells. This method relies on the specific attachment to the cell surface of a chimeric protein that consists of the IgG-binding domain of Staphylococcus aureus protein A fused in-frame with the complete sequence for firefly luciferase (proA-luc). Expression of proA-luc in Escherichia coli and its one-step affinity purification are straightforward. Attachment to cells is demonstrated to be specific and antibody dependent using several suspended and adherent cell types. Light production by cell surface-attached luciferase is continuous, linearly related to ATP concentration, and sufficient to provide nanomolar sensitivity. The spatial resolution of this method enables the observation of strictly local changes in extracellular ATP during its secretion from activated platelets. Furthermore, the activity of cell-attached luciferase is relatively refractory to the inclusion of nucleotidases in the medium, arguing for its effectiveness in cell systems possessing potent ecto-ATPases.

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.

Assembling of engineered IgG-binding protein on gold surface for highly oriented antibody immobilization

The B-domain, which is one of IgG-binding domains of staphylococcal protein A, was repeated five times and a cysteine residue was introduced at its C-terminus by a genetic engineering technique. The resulting protein, designated B5C1, retained the same IgG-binding activity as native protein A. The B5C1 was assembled on a gold plate surface by utilizing a strong affinity between thiol of cysteine and a gold surface. IgG-binding activity of B5C1 on a gold surface was much higher than that of physically adsorbed B5, which lacks cysteine residue. Furthermore, antigen-binding activity of immobilized antibody molecules through the use of assembled B5C1 on a gold surface was about 4.3 times higher than that of physically adsorbed antibody molecules. Immobilization of highly oriented antibody molecules was realized with the engineered IgG-binding protein.

Targeting of EGF-displayed protein nanoparticles with anticancer drugs.

The development of protein-based carriers for drug delivery has been well studied. We previously constructed a protein-based nanoparticle consisting of genetically engineered elastin-like polypeptides (ELPs) with a fused poly-aspartic acid tail (ELPD ). The size of the self-assembled ELPD nanoparticles was regulated by charged repulsion of the poly-aspartic acid chains. In the present study, epidermal growth factor (EGF) was genetically fused to the C-terminus of ELPD to impart an active targeting ability to the ELPD nanoparticles. We examined the nanoparticle formation with EGF as well as its targeting ability. ELPD with fused EGF was found to form nanoparticles that displayed multivalent EGFs on their surface. EGF-displayed nanoparticles loaded with the anti-cancer drug paclitaxel were internalized into cells overexpressing the EGF receptor, and induced cell death.

A functional study on polymorphism of the ATP-binding cassette transporter ABCG2: critical role of arginine-482 in methotrexate transport

Overexpression of the ATP-binding cassette transporter ABCG2 reportedly causes multidrug resistance, whereas altered drug-resistance profiles and substrate specificity are implicated for certain variant forms of ABCG2. At least three variant forms of ABCG2 have been hitherto documented on the basis of their amino acid moieties (i.e., arginine, glycine and threonine) at position 482. In the present study we have generated those ABCG2 variants by site-directed mutagenesis and expressed them in HEK-293 cells. Exogenous expression of the Arg(482), Gly(482), and Thr(482) variant forms of ABCG2 conferred HEK-293 cell resistance toward mitoxantrone 15-, 47- and 54-fold, respectively, as compared with mock-transfected HEK-293 cells. The transport activity of those variants was examined by using plasma-membrane vesicles prepared from ABCG2-overexpressing HEK-293 cells. [Arg(482)]ABCG2 transports [(3)H]methotrexate in an ATP-dependent manner; however, no transport activity was observed with the other variants (Gly(482) and Thr(482)). Transport of methotrexate by [Arg(482)]ABCG2 was significantly inhibited by mitoxantrone, doxorubicin and rhodamine 123, but not by S -octylglutathione. Furthermore, ABCG2 was found to exist in the plasma membrane as a homodimer bound via cysteinyl disulphide bond(s). Treatment with mercaptoethanol decreased its apparent molecular mass from 140 to 70 kDa. Nevertheless, ATP-dependent transport of methotrexate by [Arg(482)]ABCG2 was little affected by such mercaptoethanol treatment. It is concluded that Arg(482) is a critical amino acid moiety in the substrate specificity and transport of ABCG2 for certain drugs, such as methotrexate.

Visualization of flow-induced ATP release and triggering of Ca2+ waves at caveolae in vascular endothelial cells

Endothelial cells (ECs) release ATP in response to shear stress, a fluid mechanical force generated by flowing blood but, although its release has a crucial role in controlling a variety of vascular functions by activating purinergic receptors, the mechanism of ATP release has never been established. To analyze the dynamics of ATP release, we developed a novel chemiluminescence imaging method by using cell-surface-attached firefly luciferase and a CCD camera. Upon stimulation of shear stress, cultured human pulmonary artery ECs simultaneously released ATP in two different manners, a highly concentrated, localized manner and a less concentrated, diffuse manner. The localized ATP release occurred at caveolin-1-rich regions of the cell membrane, and was blocked by caveolin-1 knockdown with siRNA and the depletion of plasma membrane cholesterol with methyl-β-cyclodexrin, indicating involvement of caveolae in localized ATP release. Ca2+ imaging with Fluo-4 combined with ATP imaging revealed that shear stress evoked an increase in intracellular Ca2+ concentration and the subsequent Ca2+ wave that originated from the same sites as the localized ATP release. These findings suggest that localized ATP release at caveolae triggers shear-stress-dependent Ca2+ signaling in ECs.

Construction of nanoscale protein particle using temperature-sensitive elastin-like peptide and polyaspartic acid chain.

Temperature-responsive monodisperse spheres are useful for various in vivo and in vitro applications. Size, response temperature and biocompatibility are particularly important consideration with in vivo applications. In this work, we constructed fusion proteins of low antigenic elastin-like peptide (ELP) and a polyaspartic acid chain, and studied the particles that had a favorable size and temperature of formation of particle. From DLS analysis, we confirmed that some of them formed particles with less than 100nm in diameter around 37 degrees C, while the diameter of ELPs alone is larger than 1microm in diameter. The (PGVGV)(160)D(22), which is composed of a short aspartic acid chain and a long ELP region, had a tendency to form large particles. The temperature of formation and collapse of the protein particle were dependent on the length of the ELP and the polyaspartic acid chain, and the concentration of proteins. The direct observation with TEM indicated that the morphologies of the particles were spherical except when (PGVGV)(160)D(22) was used. The intensities of the environment-sensitive hydrophobic fluorescence increased at 37 degrees C more than 1.5 times as much as at 25 degrees C both in free form and modified at the ELP region. These results indicated that the polarity of the environment surround the fluorescence decreased or the movement of fluorescence was limited, and thus, implied that the ELP formed a more hydrophobic or rigid region and could hold hydrophobic drugs. These results suggest that a temperature-responsive protein particle with favorable size and temperature of formation can be constructed that is suitable for any in vitro or in vivo application.

Electrically induced neurite outgrowth of PC12 cells on the electrode surface.

Morphological differentiation of PC12 cells cultured on an indium-tin oxide (ITO) electrode has been induced to grow neurites in the absence of nerve growth factor (NGF) by electrical stimulation. Rectangular pulse wave potentials were applied to the electrode at amplitudes of 200 mV and 400 mV with frequencies of 50Hz, 500Hz, and 1 kHz. The PC12 cells differentiated most prominently at 200 mV with 100Hz. No statistically significant differences were observed among the electrically induced neurite lengths. The electrically induced differentiation was completely inhibited by a blockade of calcium influx using LaCl3. This indicates that repeated potential shift in the vicinity of a cellular membrane may stimulate morphological response, probably through calcium ion channels.

Gene expression in the electrically stimulated differentiation of PC12 cells

Cell differentiation of PC12 cells was electrically induced to grow neurites in the absence of nerve growth factor (NGF) on the electrode surface, of which potential was modulated by a rectangular wave of potential. The electric stimulation induced the c-fos expression which is essential for cell differentiation. Non-specific calcium channel blocker, lanthanum ion, inhibited the electrically induced differentiation, while NGF-induced differentiation was not suppressed. An L-type calcium channel blocker, nifedipine, also inhibited the electrically induced calcium influx and c-fos expression. Moreover, a stretch-activated (SA) channel blocker, gadolinium ion, inhibited the electrically stimulated differentiation by blocking the calcium influx, but gave no prominent effects on the potassium ion-induced differentiation. Chelerythrine, a specific protein kinase C (PKC) inhibitor, almost inhibited the cell differentiation by the electric stimulation but not by the NGF treatment. These results indicate that the alternative potential may stimulate cell differentiation through a PKC cascade.

Construction of multi-functional extracellular matrix proteins that promote tube formation of endothelial cells

We developed artificial extracellular matrix proteins designed to have collagen-binding activity and active functional units that promote network formation of vascular endothelial cells. We engineered a laminin-derived IKVAV sequence, which stimulates capillary network formation of vascular endothelial cells, to incorporate into an elastin-derived structural unit. The designed fusion protein also had a cell-adhesive RGD sequence and a collagen-binding domain derived from fibronectin. The resultant fusion protein could bind to collagen type I and promote angiogenic activity of collagen gel. The collagen-binding domain also had slight angiogenic activity; however, the designed fusion protein also enhanced cellular migration activity. The engineering strategy of designing multi-functional ECM proteins has a possibility for supporting current tissue engineering techniques.