Kazuaki Kajimoto

A comparative study between nanoparticle-targeted therapeutics and bioconjugates as obesity medication

Antiangiogenesis has been the focus of a new strategy for the treatment of obesity. However, little is known regarding the issue of whether targeting angiogenesis by nanoparticle-targeted therapeutic is advantageous or not in debugging the co-morbidity associated with diet-induced obesity (DIO) and the metabolic syndrome. We report herein on the positive effect of prohibitin (an adipose vascular marker)-targeted nanoparticle (PTNP) encapsulated in a proapoptotic peptide [(D)(KLAKLAK)₂, KLA] on DIO and dysfunctional adipose tissue, a major mediator of the metabolic syndrome, as evidenced by ectopic fat deposition. The systemic injection of DIO mice with a low dose of KLA-PTNP, rather than a bioconjugate composed of the same targeting peptide and KLA (Adipotide) resulted in a reduction in body weight, as evidenced by a significant decrease in serum leptin levels, in parallel with an antiobesity effect on dysfunctional adipose cells, including adipocytes and macrophages. In addition, the KLA-PTNP treatment resulted in a reduction in ectopic fat deposits in liver and muscle with the lipolytic action of elevated serum adiponectin, with no detectable hepatoxicity. Notably, drug delivery via PTNP that had accumulated in obese fat via the enhanced permeability and retention effect was enhanced by multivalent active targeting and cytoplasmic delivery into adipose endothelial cells via escaping from endosomes/lysosomes. Thus, vascular-targeted nanotherapy has the potential to contribute to the control of adipose function and ectopic fat deposition associated with obesity and the metabolic syndrome.

Noninvasive delivery of siRNA into the epidermis by iontophoresis using an atopic dermatitis-like model rat

Topical application of siRNA to the skin should be an effective treatment for serious skin disorders, such as atopic dermatitis. However, it is difficult to introduce hydrophilic macromolecules, including siRNA, into the skin by conventional methods. For efficient delivery of siRNA, we examined an iontophoretic technique, since it is suitable for the delivery of charged molecules. Naked siRNA effectively accumulated in the epidermis (and not in the dermis) after iontophoretic delivery. In contrast, siRNA did not penetrate tape-stripped skin by passive diffusion. In a rat model of atopic dermatitis, skin was sensitized with ovalbumin to stimulate IL-10 mRNA expression as observed in skin lesions. Iontophoretic delivery of anti-IL-10 siRNA significantly reduced (73%) the level of IL-10 mRNA. In conclusion, we successfully delivered naked siRNA into the epidermis and concomitantly suppressed the expression of an endogenous immuno-regulatory cytokine.

Ligand-based targeted delivery of a peptide modified nanocarrier to endothelial cells in adipose tissue

Ligand-based targeted delivery is an emerging platform in nanomedicine. We report herein on a peptide modified nanocarrier for a ligand-based targeted delivery system. The liposomal surface of the carrier was first modified with a linear peptide, followed by an adipose tissue-specific circular peptide (KGGRAKD) via a polyethylene glycol (PEG) spacer. To evaluate the specificity of the carrier, we purified primary cells from the endothelium of adipose tissue. The liposomes bound only to isolated primary cultured endothelial cells derived from inguinal adipose tissue (pcEC-IWAT) and not to other endothelial cell lines, such as MBEC-4 and MFLM-4. Cellular uptake was confirmed both qualitatively and quantitatively by confocal laser scanning microscopy (CLSM) and flow cytometry. The mechanism for the intracellular uptake of tPep-PEG-LPs into pcEC-IWAT, as evidenced by three independent experiments, involves saturation of receptor binding sites by excess free peptide, the blocking of receptors by an anti-prohibitin antibody and low temperature (4°C) experiments, resulting in the inhibition of uptake of tPep-PEG-LPs into pcEC-IWAT, suggesting that receptor mediated endocytosis largely contributed to the observed cellular uptake. A co-localization study using double labeled modified liposomes (lipid membrane: NBD-DOPE and aqueous phase: rhodamine) indicated that a predominant part of tPep-PEG-LPs was found without co-localization with lysosomes and retained their intactness. The selective delivery of tPep-PEG-LPs to endothelial cells in adipose tissue represents a potential approach for the design of diverse nanocarrier-based targeted delivery systems for targeting the vasculature in adipose tissue.

Cell penetrating peptide-mediated systemic siRNA delivery to the liver

The cell-penetrating peptide (CPP) is one of the most attractive tools for efficiently delivering biomolecules to a target organelle. Here, we describe the use of octaarginine (R8)-modified lipid nanoparticles for the efficient and targeted in vivo delivery of siRNA to the liver. In this study, SR-BI (a scavenger receptor class B, member 1) was targeted by this nanoparticle. Our results demonstrate that R8-modified lipid nanoparticles can be used for the efficient and targeted delivery of liver siRNA to induce the specific knock-down of an endogenous gene with minimum liver toxicity and immune response, and that this CPP based technology holds considerable promise for further in vivo biological applications of siRNA.

Multifunctional envelope-type nano device for controlled intracellular trafficking and selective targeting in vivo

Nanomedicine is expected to be a basic technology for using nucleic acids as a drug, in which treating the cause of diseases represent the ultimate therapy. However, a sophisticated delivery system is required for efficient delivery of RNA/DNA, since these compounds need precise control of intracellular trafficking as well as biodistribution. Here we report on the use of a multifunctional envelope-type nano device (MEND) which is capable of intracellular trafficking such as endosomal escape, delivery to mitochondria, as well as active targeting to selective tissues/cells in vivo. In this review, we focused on the controlled intracellular trafficking of antigens for advanced immunotherapy, and then introduced a mitochondrial delivery system as an organelle targeting system for unmet medical needs. We also provide a successful in vivo delivery of siRNA to the liver based on a newly designed pH-responsive cationic lipid. Finally we will discuss an important role of an active targeting system using a peptide ligand to adipose vasculature. These progresses in drug delivery system will break through the barriers exist in our body, tissues and cells and open a window for future Nanomedicine.

Lipid envelope-type nanoparticle incorporating a multifunctional peptide for systemic siRNA delivery to the pulmonary endothelium

A system that permits the delivery of cargoes to the lung endothelium would be extraordinarily useful in terms of curing a wide variety of lung-related diseases. This study describes the development of a multifunctional envelope-type nanodevice (MEND) that targets the lung endothelium, delivers its encapsulated siRNA to the cytoplasm, and eradicates lung metastasis. The key to the success can be attributed to the presence of a surface-modified GALA peptide that has dual functions: targeting the sialic acid-terminated sugar chains on the pulmonary endothelium and subsequently delivering the encapsulated cargoes to the cytosol via endosomal membrane fusion, analogous to the influenza virus. The active targeting of MENDs without the formation of large aggregates was verified by intravital real-time confocal laser scanning microscopy in living lung tissue. The GALA-modified MEND is a promising carrier that opens a new generation of therapeutic approaches for satisfying unmet medical needs in curing lung diseases.

Leptin-derived peptide, a targeting ligand for mouse brain-derived endothelial cells via macropinocytosis

Leptin is an appetite regulatory hormone that is secreted into the blood circulation by adipose tissue, and functions in the central nerve system (i.e. hypothalamus) by crossing the blood brain barrier (BBB). In the present study, we investigated the function of a leptin-derived peptide (Lep(70-89)) as a ligand for mouse brain-derived endothelial cells (MBEC4). Lep(70-89)-modified liposomes, prepared with a polyethyleneglycol (PEG) spacer (Lep(70-89)-PEG-LPs) exhibited a significantly higher cellular uptake than peptide-unmodified liposomes (PEG-LPs). Furthermore, cellular uptake was inhibited by amiloride, while no significant inhibitory effect was observed by the presence of chlorpromazine and filipin III, suggesting that macropinocytosis largely contributed to the cellular uptake of Lep(70-89)-PEG-LPs. Imaging studies revealed that Lep(70-89)-PEG-LPs were not colocalized with endosome/lysosomes, whereas neutral dextran (70 kDa) was predominantly colocalized with these compartments. This indicates that Lep(70-89)-PEG-LPs are taken up via macropinocytosis and are subject to non-classical intracellular trafficking, resulting in the circumvention of lysosomal degradation in endothelial cells.

Noninvasive and persistent transfollicular drug delivery system using a combination of liposomes and iontophoresis

Iontophoresis is a promising technique for enhancing transdermal administration of charged drugs. However, conventional iontophoresis is not sufficient for effective delivery of large, hydrophilic, or electrically neutral molecules. In this study, we utilized charged liposomes as carriers, focused on a transfollicular route for delivery of the liposomes, and optimized iontophoretic conditions and lipid composition for this method in both in vitro and in vivo conditions. As a result, we identified the optimum condition (lipid composition: DOTAP/EPC/Chol=2:2:1, current supply: 0.45mA/cm(2), duration: 1h) for effective iontophoretic delivery of aqueous solution, which cannot be transferred into the skin without charged liposomes. We also examined the pharmacological effects of iontophoresis of liposomes encapsulating insulin (INS-lipo) using a rat model of type I diabetes. Interestingly, iontophoresis of INS-lipo onto a diabetes rat skin resulted in a gradual decrease in blood glucose levels, with levels reaching 20% of initial values at 18h after administration. These lower blood glucose levels were maintained for up to 24h. Significant amount of insulin were also detected in plasma 18h after iontophoresis of INS-lipo. We succeeded in developing a non-invasive and persistent transfollicular drug delivery system that used a combination of liposomes and iontophoresis.

Vascular-targeted nanotherapy for obesity: unexpected passive targeting mechanism to obese fat for the enhancement of active drug delivery.

We previously reported that nanoparticles (NPs) modified with a prohibitin-homing peptide ligand via a short PEG(2kDa)-spacer could deliver its pay-load into the cytoplasm of endothelial cells in murine adipose tissue and escape from endosomes/lysosomes in vitro. We herein report, for the first time, on a dual-targeting strategy for mediating the enhanced targeting activity of NPs to adipose endothelial cells in diet-induced obesity (DIO). The targeted accumulation of prohibitin-targeted nanoparticles (PTNP), modified with a peptide ligand via a long PEG-linker, was significantly increased in white fat vessels of normal healthy mice compared to the other non-PEGylated targeted NPs, whereas the undesired accumulation of PTNP in the liver was considerably reduced. These results demonstrate that the PEGylation of targeted NPs is a critical factor in maximizing the in vivo targeted delivery of NPs and can be attributed to a significant decrease in recognition by the reticuloendothelial system. After systemic administration to DIO mice, PTNP exclusively accumulated in both adipose vessels and angiogenic clusters of obese fat cells. Surprisingly, PEGylated NPs with no active targeting moieties also accumulated in these clusters, demonstrating that the nanoscaled carriers passively accumulate in clusters via a mechanism similar to that for the enhanced permeability and retention effect, as has been well established in tumor targeting. Therefore, the enhanced delivery of PTNP appears to be mediated by both passive accumulation to angiogenic regions and active recognition by endothelial cells. Thus, the systemic administration of a proapoptotic peptide with the delivery via PTNP significantly reduced the body weight of DIO mice, as evidenced by the targeted ablation of adipose endothelial cells. These findings are potentially useful in terms of the design and development of vascular-targeted nanotherapy in the effective control of obesity.

Noninvasive and efficient transdermal delivery of CpG-oligodeoxynucleotide for cancer immunotherapy

Oligodeoxynucleotides containing unmethylated cytosine-phosphate-guanosine motifs (CpG-ODN) possess immunostimulatory effects and potential antitumor activity. Since the skin is an easily available site of administration of CpG-ODN due to its accessibility and the presence of abundant antigen presenting cells, it is expected that the application of CpG-ODN to the skin would induce systemic immune response and antitumor activity. However, it is difficult to deliver hydrophilic macromolecules including CpG-ODN through the skin. We have previously demonstrated that small interfering RNA (siRNA) was efficiently delivered into rat epidermis by iontophoresis. In this report, we investigate the effect of transdermal iontophoretic delivery of CpG-ODN on the induction of immune responses and antitumor activity against B16F1 melanoma in mice. Iontophoresis promoted CpG-ODN delivery into the epidermis and dermis. Furthermore, iontophoretic delivery of CpG-ODN to the skin induced the expression of proinflammatory and Th1-type cytokines in the skin and draining lymph node. Finally, transdermal iontophoretic delivery of CpG-ODN led to antitumor activity against B16F1 melanoma. Interestingly, the CpG-ODN administration site is not restricted to the tumor area. In conclusion, CpG-ODN delivered transdermally induced potent antitumor activity, and our system is expected to serve as a simple and noninvasive approach for cancer immunotherapy.