Yuya Nishimura

A display of pH-sensitive fusogenic GALA peptide facilitates endosomal escape from a Bio-nanocapsule via an endocytic uptake pathway

BackgroundAn affibody-displaying bio-nanocapsule (ZHER2-BNC) with a hepatocyte specificity derived from hepatitis B virus (HBV) was converted into an affibody, ZHER2, that recognizes HER2 receptors. This affibody was previously reported to be the result of the endocytosis-dependent specific uptake of proteins and siRNA into target cancer cells. To assist the endosomal escape of inclusions, a helper lipid with pH-sensitive fusogenic ability (1,2-dioleoyl-sn-glycero-3-phos phoethanolamine; DOPE) was conjugated with a ZHER2-BNC.FindingsIn this study, we displayed a pH-sensitive fusogenic GALA peptide on the surface of a particle in order to confer the ability of endosomal escape to a ZHER2-BNC. A GALA-displaying ZHER2-BNC purified from yeast uneventfully formed a particle structure. Furthermore, endosomal escape of the particle was facilitated after endocytic uptake and release of the inclusions to the cytoplasm without the cell toxicity.ConclusionThe genetic fusion of a GALA peptide to the virus-like particle confers the ability of endosomal escape.

Targeting cancer cell-specific RNA interference by siRNA delivery using a complex carrier of affibody-displaying bio-nanocapsules and liposomes

BackgroundSmall interfering RNA (siRNA) has attracted attention in the field of nucleic acid medicine as a RNA interference (RNAi) application that leads to gene silencing due to specific messenger RNA (mRNA) destruction. However, since siRNA is unstable in blood and unable to cross the cell membrane, encapsulation of siRNA into a carrier is required.ResultsIn this study, we used a carrier that combined ZHER2-displaying bio-nanocapsule (derived from hepatitis B virus surface antigen) and liposomes in a complex in order to investigate the feasibility of effective and target-cell-specific RNAi applications. As a result, by observing RNAi only in HER2-expressing breast cancer cells, using our proposed methodology, we successfully demonstrated target-cell-specific delivery and effective function expression of siRNA.ConclusionsThese findings show that, in the field of nucleic acid medicine, ZHER2-BNC/LP can be a useful carrier for siRNA delivery, and could also become a useful tool for gene silencing and to accomplish protein knock-down.

Affibody-displaying bionanocapsules for specific drug delivery to HER2-expressing cancer cells

A novel HER2-targeted carrier was developed using bionanocapsules (BNCs). Bionanocapsules (BNCs) are 100-nm hollow nanoparticles composed of the L-protein of hepatitis B virus surface antigen. An affibody of HER2 was genetically displayed on the BNC surface (Z(HER2)-BNC). For the investigation of binding affinity, Z(HER2)-BNC was incubated with the cancer cell lines SK-BR-3 (HER2 positive), and MDA-MB-231 (HER2 negative). For analysis of HER2 targeting specificity, Z(HER2)-BNC or Z(WT)-BNC (without affibody) was incubated with both SK-BR-3 and MDA-MB-231 cells by time lapse and concentration. For the delivery of encapsulated molecules (calcein), fluorescence of Z(HER2)-BNC mixed with liposomes was also compared with that of Z(WT)-BNC and nude liposomes by incubation with SK-BR-3 cells. As a result, Z(HER2)-BNC-liposome complex demonstrated the delivery to HER2-expressing cells (SK-BR-3) with a high degree of specificity. This indicates that genetically engineered BNCs are promising carrier for cancer treatment.

Granting specificity for breast cancer cells using a hepatitis B core particle with a HER2-targeted affibody molecule

Capsid-like particles consisting of a hepatitis B core (HBc) protein have been studied for their potential as carriers for drug delivery systems (DDS). The hollow HBc particle, which is formed by the self-assembly of core proteins comprising 183 aa residues, has the ability to bind to various cells non-specifically via the action of an arginine-rich domain. In this study, we developed an engineered HBc particle that specifically recognizes and targets human epidermal growth factor receptor-related 2 (HER2)-expressing breast cancer cells. To despoil the non-specific binding property of an HBc particle, we genetically deleted the C-terminal 150-183 aa part of the core protein that encodes the arginine-rich domain (ΔHBc). Then, we genetically inserted a Z(HER2) affibody molecule into the 78-81 aa position of the core protein to confer the ability of target-cell-specific recognition. The constructed Z(HER2)-displaying HBc (Z(HER2)-ΔHBc) particle specifically recognized HER2-expressing SKBR3 and MCF-7 breast cancer cells. In addition, the Z(HER2)-ΔHBc particle exhibited different binding amounts in accordance with the HER2 expression levels of cancer cells. These results show that the display of other types of affibody molecules on HBc particles would be an expandable strategy for targeting several kinds of cancer cells that would help enable a pinpoint DDS.

Complex carriers of affibody-displaying bio-nanocapsules and composition-varied liposomes for HER2-expressing breast cancer cell-specific protein delivery.

A bio-nanocapsule (BNC), a hollow particle composed of hepatitis B virus (HBV) surface antigen (HBsAg), and liposome (LP) conjugation method (BNC/LP) has been recently developed by . The BNC/LP complex carrier could successfully deliver fluorescence-labeled beads (100 nm) into liver cells. In this study, we report the promising delivery of proteins incorporated in the complex carriers, which were prepared by the BNC/LP conjugation method with specificity-altered BNC and composition-varied LPs. The specificity-altered BNC, ZHER2-BNC was developed by replacing the hepatocyte recognition site of BNC with ZHER2 binding to HER2 receptor specifically. Using green fluorescent protein (GFP; 27 kDa) and cellular cytotoxic protein (exotoxin A; 66 kDa) for the delivery, we herein present the impact of different charges attributed to the composition of the LP on specific cell targeting and cellular uptake of the complex carriers. In addition, we demonstrate that the mixture prepared by mixing LPs with helper lipid possessing endosomal escaping ability boosts the functional expression of the cellular cytotoxic exotoxin A activity specifically. Finally, we further show the blending ratio of the LP mixture and ZHER2-BNC is a critical factor in determining the highly-efficient expression of the cytotoxic activity of exotoxin A.

Engineering hepatitis B virus core particles for targeting HER2 receptors in vitro and in vivo

Hepatitis B Virus core (HBc) particles have been studied for their potential as drug delivery vehicles for cancer therapy. HBc particles are hollow nano-particles of 30–34 nm diameter and 7 nm thick envelopes, consisting of 180–240 units of 21 kDa core monomers. They have the capacity to assemble/dis-assemble in a controlled manner allowing encapsulation of various drugs and other biomolecules. Moreover, other functional motifs, i.e. receptors, receptor binding sequences, peptides and proteins can be expressed. This study focuses on the development of genetically modified HBc particles to specifically recognise and target human epidermal growth factor receptor-2 (HER2)-expressing cancer cells, in vitro and in vivo, for future cancer therapy. The non-specific binding capacity of wild type HBc particles was reduced by genetic deletion of the sequence encoding arginine-rich domains. A specific HER2-targeting was achieved by expressing the ZHER2 affibodies on the HBc particles surface. In vitro studies showed specific uptake of ZHER2-ΔHBc particles in HER2 expressing cancer cells. In vivo studies confirmed positive uptake of ZHER2-ΔHBc particles in HER2-expressing tumours, compared to non-targeted ΔHBc particles in intraperitoneal tumour-bearing mice models. The present results highlight the potential of these nanocarriers in targeting HER2-positive metastatic abdominal cancer following intra-peritoneal administration.

Characterization of titanium dioxide nanoparticles modified with polyacrylic acid and H2O2 for use as a novel radiosensitizer

Abstract An induction of polyacrylic acid-modified titanium dioxide with hydrogen peroxide nanoparticles (PAA-TiO2/H2O2 NPs) to a tumor exerted a therapeutic enhancement of X-ray irradiation in our previous study. To understand the mechanism of the radiosensitizing effect of PAA-TiO2/H2O2 NPs, analytical observations that included DLS, FE-SEM, FT-IR, XAFS, and Raman spectrometry were performed. In addition, highly reactive oxygen species (hROS) which PAA-TiO2/H2O2 NPs produced with X-ray irradiation were quantified by using a chemiluminescence method and a EPR spin-trapping method. We found that PAA-TiO2/H2O2 NPs have almost the same characteristics as PAA-TiO2. Surprisingly, there were no significant differences in hROS generation. However, the existence of H2O2 was confirmed in PAA-TiO2/H2O2 NPs, because spontaneous hROS production was observed w/o X-ray irradiation. In addition, PAA-TiO2/H2O2 NPs had a curious characteristic whereby they absorbed H2O2 molecules and released them gradually into a liquid phase. Based on these results, the H2O2 was continuously released from PAA-TiO2/H2O2 NPs, and then released H2O2 assumed to be functioned indirectly as a radiosensitizing factor.

Mutation of arginine residues to avoid non-specific cellular uptakes for hepatitis B virus core particles

BackgroundThe hepatitis B virus core (HBc) particle is known as a promising new carrier for the delivery of drugs and nucleic acids. However, since the arginine-rich domain that is located in the C-terminal region of the HBc monomer binds to the heparan sulphate proteoglycan on the cell surface due to its positive charge, HBc particles are introduced non-specifically into a wide range of cells. To avoid non-specific cellular uptake with the intent to control the ability of cell targeting, we individually replaced the respective arginine (R) residues of the arginine-rich domain located in amino acid positions 150–159 in glycine (G) residues.ResultsThe mutated HBc particles in which R154 was replaced with glycine (G) residue (R154G) showed a drastic decrease in the ability to bind to the heparan sulphate proteoglycan and to avoid non-specific cellular uptake by several types of cancer cells.ConclusionsBecause this mutant particle retains most of its C-terminal arginine-rich residues, it would be useful in the targeting of specificity-altered HBc particles in the delivery of nucleic acids.

An affinity chromatography method used to purify His-tag-displaying bio-nanocapsules.

A bio-nanocapsule derived from the hepatitis B virus (HBV) is expected to be useful as a drug delivery system carrier. Because various types of bio-nanocapsules have been developed, a simple and versatile purification method for bio-nanocapsules would be useful. Therefore, this study was focused on establishing a simple purification method using affinity chromatography by inserting a histidine tag (His-tag) into a bio-nanocapsule. The method achieved a simple, one-step purification with a yield that was 2.5-fold higher than conventional ultracentrifugation, and thus would be a desirable alternative method for recombinant virus-like particle purification.

Protein-encapsulated bio-nanocapsules production with ER membrane localization sequences

Bio-nanocapsules (BNCs) are hollow nanoparticles composed of the L protein of hepatitis B virus (HBV) surface antigen (HBsAg), which can specifically introduce genes and drugs into various kinds of target cells. Although the classic electroporation method has typically been used to introduce highly charged molecules such as DNA, it is rarely adopted for proteins due to its very low efficiency. In this study, a novel approach to the preparation of BNC was established whereby a target protein was pre-encapsulated during the course of nanoparticle formation. Briefly, because of the process of BNC formation in a budding manner on the endoplasmic reticulum (ER) membrane, the association of target proteins to the ER membrane with lipidation sequences (ER membrane localization sequences) could directly generate protein-encapsulating BNC in collaboration with co-expression of the L proteins. Since the membrane-localized proteins are automatically enveloped into BNCs during the budding event, this method can be protect the proteins and BNCs from damage caused by electroporation and obviate the need for laborious consideration to study the optimal conditions for protein encapsulation. This approach would be a useful method for encapsulating therapeutic candidate proteins into BNCs.