Insulin therapy maintains the performance of PVA-coated PCL grafts in a diabetic rat model.

Vascular tissue engineering has shown promising results in "healthy" animal models. However, studies on the efficacy of artificial grafts under "pathological conditions" are limited. Therefore, in this study, we aimed to characterize the performance of polyvinyl alcohol (PVA)-coated poly-ε-caprolactone (PCL) grafts (PVA-PCL grafts) under diabetic conditions. To this end, PCL grafts were produced via electrospinning and coated with the hydrophilic PVA polymer, while a diabetic rat model (DM) was established via streptozotocin injection. Thereafter, the performance of the graft in the infrarenal abdominal aorta of the rats was evaluated in vivo. Thus, we observed that the healthy group showed CD31 positive/αSM positive cells in the graft lumen. Further, the patency rate of the PVA-PCL graft was 100% at 2 weeks (n = 7), while all the DM rats (n = 8) showed occluded grafts. However, the treatment of DM rats with neutral protamine Hagedorn insulin (tDM) significantly improved the patency rate (100%; n = 5). Furthermore, the intimal coverage rate corresponding to the tDM group was comparable to that of the healthy group at 2 weeks (tDM vs. healthy: 16.1% vs. 14.7%, p = 0.931). Therefore, the present study demonstrated that the performance of the PVA-PCL grafts was impaired in DM rats; however, insulin treatment reversed this impairment. These findings highlighted the importance of using a model that more closely resembles the cases that are encountered in clinical practice to achieve a clinically applicable vascular graft with a small diameter.

MITO-Porter: A liposome-based carrier system for delivery of macromolecules into mitochondria via membrane fusion.

Mitochondria are the principal producers of energy in higher cells. Mitochondrial dysfunction is implicated in a variety of human diseases, including cancer and neurodegenerative disorders. Effective medical therapies for such diseases will ultimately require targeted delivery of therapeutic proteins or nucleic acids to the mitochondria, which will be achieved through innovations in the nanotechnology of intracellular trafficking. Here we describe a liposome-based carrier that delivers its macromolecular cargo to the mitochondrial interior via membrane fusion. These liposome particles, which we call MITO-Porters, carry octaarginine surface modifications to stimulate their entry into cells as intact vesicles (via macropinocytosis). We identified lipid compositions for the MITO-Porter which promote both its fusion with the mitochondrial membrane and the release of its cargo to the intra-mitochondrial compartment in living cells. Thus, the MITO-Porter holds promise as an efficacious system for the delivery of both large and small therapeutic molecules into mitochondria.

Myocardial tissue engineering: the extracellular matrix.

More than a decade after the first reports on successful three-dimensional cardiac cell culture for experimental and potential therapeutic application, the interest and experimental efforts in the field of myocardial tissue engineering continues to grow. The hope that tissue cultures may one day act as graft substitute for malfunctioning myocardium continues to drive current scientific activity. Against this background interest seem to have progressively shifted towards the aim of engineering single tissue components. Accordingly, elements of the extracellular matrix (ECM) have gained increasing attention as potentially crucial mediators in developing and maintaining the characteristics of three-dimensional cardiac cell cultures. The ECM is now no longer regarded as merely a scaffold for developing tissue, a concept that is widely acknowledged in modern tissue engineering. The understanding of the role of precursor and stem cells has highlighted new complicated aspects of cell proliferation and differentiation and ECM proves to play an important role in providing essential signals to influence major intracellular pathways such as proliferation, differentiation and cell metabolism. Furthermore, progress in biochemical engineering has provided the perspective of application of synthetic ECM-linked molecules with bioactive potential. With the advent and continuous refinement of cell removal techniques, a new class of native acellular ECM has emerged with some striking advantages. The presently available ECM materials aim to closely resemble the in vivo microenvironment by acting as an active component of the developing tissue construct. It is therefore not surprising that most of the focus in myocardial tissue engineering has been on cell-matrix interaction, for both naturally derived and synthetic ECM. This article provides a review of established models of myocardial tissue engineering with respect to the employed ECM materials including current frontiers in material development.

Mutagenic effects of 8-hydroxy-dGTP in live mammalian cells.

The mutagenicity of an oxidized form of dGTP, 8-hydroxy-2'-deoxyguanosine 5'-triphosphate (8-OH-dGTP), was examined using COS-7 cells. 8-OH-dGTP and supF shuttle plasmid DNA were cointroduced by means of cationic liposomes, and the DNAs replicated in the cells were recovered and then transfected into Escherichia coli. 8-OH-dGTP induced A:T-->C:G substitution mutations in the COS-7 cells. This result agrees with previous observations indicating that DNA polymerases misincorporate 8-OH-dGTP opposite A in vitro, and that the oxidized deoxyribonucleotide induces A:T-->C:G transversions in E. coli. These results constitute the first direct evidence to show that 8-OH-dGTP actually induces mutations in living mammalian cells.

Mitochondrial drug delivery and mitochondrial disease therapy--an approach to liposome-based delivery targeted to mitochondria.

Recent progress in genetics and molecular biology has provided useful information regarding the molecular mechanisms associated with the mitochondrial diseases. Genetic approaches were initiated in the late 1980s to clarify the gene responsible for various mitochondrial diseases, and information concerning genetic mutations is currently used in the diagnosis of mitochondrial diseases. Moreover, it was also revealed that mitochondria play a central role in apoptosis, or programmed cell death, which is closely related to the loss of physiological functions of tissues. Therefore, drug therapies targeted to the mitochondria would be highly desirable. In spite of the huge amount of mechanism-based studies of mitochondrial diseases, effective therapies have not yet been established mainly because of the lack of an adequate delivery system. To date, numerous investigators have attempted to establish a mitochondrial drug delivery system. However, many problems remain to be overcome before a clinical application can be achieved. To fulfill a drug delivery targeted to mitochondria, we first need to establish a method to encapsulate various drugs, proteins, peptides, and genes into a drug carrier depending on their physical characteristics. Second, we need to target it to a specific cell. Finally, multi-processes of intracellular trafficking should be sophisticatedly regulated so as to release a drug carrier from the endosome to the cytosol, and thereafter to deliver to the mitochondria. In this review, we describe the current state of the development of mitochondrial drug delivery systems, and discuss the advantage and disadvantage of each system. Our current efforts to develop an efficient method for the packaging of macromolecules and regulating intracellular trafficking are also summarized. Furthermore, novel concept of "Regulation of intramitochondrial trafficking" is proposed herein as a future challenge to the development of a mitochondrial drug delivery system.

[Development of multifunctional envelope type artificial viral-like gene delivery system].

This review introduces a new concept "Programmed Packaging" to develop a non-viral gene delivery system. Based on this concept, multifunctional envelope type nano devices (MEND) were developed for in vitro, in situ and in vivo conditions. A quantitative study to identify a rate limiting step in intracellular trafficking was also shown between viral and non-viral vectors, which indicated an important role of controlled intranuclear disposition for development a safe and efficient non-viral gene delivery system. This review will provide a future direction of non-viral gene delivery system.

Mitochondrial delivery of mastoparan with transferrin liposomes equipped with a pH-sensitive fusogenic peptide for selective cancer therapy.

Mastoparan (MP), a potent facilitator of mitochondrial permeability transition (PT), could be used as an antitumor agent, if it were encapsulated in a tumor selective delivery system. We recently developed transferrin-modified liposomes (Tf-L) with a pH-sensitive fusogenic peptide (GALA), which delivers an encapsulated fluorescent marker into cytosol efficiently. In this study, we encapsulated MP into Tf-L with GALA for the selective delivery to mitochondria of tumor cells. The MP showed potent PT activity at concentrations above 25 microM in a homogenate of K 562 cells as well as in isolated mitochondria in the presence of phosphate. Tf-L equipped with cholesteryl GALA can release encapsulated sulforhodamine B, while Tf-L failed, as evidenced by confocal laser scanning microscopy. The MP, which was delivered with Tf-L with GALA, released cytochrome c (cyt c) from mitochondria to the cytosol, while free MP released cyt c not only to the cytosol but also extracellulary. These results demonstrate the utility of MP in Tf-L with GALA for cancer therapy.

Pharmacokinetics of targeting with liposomes.

The optimization of drug disposition in the body leads to an increase in its therapeutic effect and to a decrease in adverse effects. Liposomes can serve as a potential drug carrier for achieving this. However, the behavior of a drug carrier system under in vivo conditions is complex. Therefore, a more complete understanding of the pharmacokinetics of liposomes themselves, as well as that of the encapsulated drug, is required. The optimization of the pharmacokinetics of liposomes can be performed by linking a pharmacodynamic model of the free drugs that are encapsulated into liposomes. Sensitivity analysis was applied to optimize the delivery system to maximize the antitumor effect of liposomal doxorubicin (DOX). Advanced technology for ligand-mediated selective targeting and intracellular targeting is also introduced for antitumor agents and for gene delivery systems.

PK-PD modeling of 1-(3-C-ethynyl-beta-D-ribo-pentofuranosyl)cytosine and the enhanced antitumor effect of its phospholipid derivatives in long-circulating liposomes.

The efficacy of an antitumor nucleoside, 1-(3-C-ethynyl-beta-d-ribo-pentofuranosyl)cytosine (3'-ethynylcytidine, ECyd), was analyzed in vitro and in vivo. The in vivo antitumor effect of ECyd encapsulated into long-circulating liposomes was also examined. Based on pharmacokinetic (PK) and pharmacodynamic (PD) analyses, a model that quantitatively explains the in vivo effects of ECyd was proposed, using the concept of minimum effective concentration. The model suggests that ECyd followed a time-dependent mechanism of action in vivo, and that availability of ECyd in tumor tissue was highly important. To improve the availability of ECyd, its phospholipid derivatives were synthesized and encapsulated into long-circulating liposomes, which increased the antitumor effect. These results indicate that it is very important to design carriers of antitumor drugs based on PK-PD modeling.

Cell cycle dependent transcription, a determinant factor of heterogeneity in cationic lipid-mediated transgene expression.

BACKGROUND: Heterogeneity of transgene expression, the presence or absence (below the limit of detection) of transgene expression on a cell-by-cell basis, is a severe disadvantage in the use of cationic lipid-mediated gene vectors for gene therapy and experiments in molecular biology. Understandings of intracellular trafficking and the function (transgene expression) of vectors related to cellular physiology are essential in terms of clarifying the mechanism underlying the heterogeneity. METHODS: To distinguish the contribution of nuclear transfer efficiency and subsequent intranuclear transcription efficiency to the overall heterogeneity in transgene expression, a novel imaging system was established for the dual visualization of the nuclear transfer of pDNA and marker gene expression (lacZ) in single cells. RESULTS: The expression of LacZ occurred in only approximately 30% of HeLa cells of the nuclear pDNA-positive cells, indicating that intranuclear transcription efficiency contributed to the heterogeneity. Dual imaging against synchronized cells further revealed that the efficiency of nuclear delivery was comparable irrespective of cell cycle status, which is contrary to the generally accepted hypothesis that nuclear import of pDNA is enhanced during cell division when the nuclear membrane structure is perturbed. The most significant finding in the present study is that nuclear transcription efficiency in terms of the ratio of LacZ-positive cells to nuclear pDNA-positive cells drastically increased in the late S and G2/M phase. CONCLUSIONS: This is the first demonstration to show that cell cycle dependent intranuclear transcription appears to be responsible for the overall heterogeneity of transgene expression.

Visualization of intracellular trafficking of exogenous DNA delivered by cationic liposomes.

To visualize the intracellular trafficking of exogenous DNAs delivered by cationic liposomes, rhodamine-labeled DNAs were transfected into NIH3T3 cells and observed by confocal laser microscopy. After 0.5- to 1-h incubations, the DNAs reached the nucleus with a much higher frequency than that expected from the cell division rate. This result suggests that DNAs can enter the nucleus in the presence of the nuclear membrane. Interestingly, some DNAs appeared to extend through the nuclear membrane in the aggregated form which were much larger than the nuclear pore complex. The DNAs which have passed through the nuclear membrane were stained with SYTO 24, a DNA labeling reagent. The stained part may be "naked" DNA that is free of lipids or proteins. This observation indicates that a complex containing DNA fuses with the nuclear membrane and then naked DNA is released into the nucleus.

Transferrin-modified liposomes equipped with a pH-sensitive fusogenic peptide: an artificial viral-like delivery system.

Liposomes are one of the most promising systems for selective cellular targeting via introduction of specific ligands for cell-surface receptors. After being taken up by the cells, these liposomes usually follow intracellular pathways of receptor-mediated endocytosis. Control of intracellular trafficking is required for optimized drug delivery. In this study, we elucidated the intracellular fate of transferrin-modified liposomes and succeeded in altering it by introducing the pH-sensitive fusogenic peptide, GALA (WEAALAEALAEALAEHLAEALAEALEALAA). Transferrins that are chemically attached to a liposomal surface (Tf-L) were internalized via receptor-mediated endocytosis more slowly than unmodified transferrins. In contrast to the recyclable nature of transferrin, liposome-attached transferrins together with encapsulated rhodamines were retained in vesicular compartments. When GALA was introduced into liposomal membranes using a cholesteryl moiety for anchoring (Chol-GALA), rhodamines were efficiently released and diffused into the cytosol. The addition of GALA to the Tf-L-containing medium or the encapsulation of GALA in Tf-L did not induce similar effects. These results clearly indicate that GALA must be present on the surface of liposomes to exert its function. In vitro energy transfer and dynamic light scattering experiments suggested that the endosomal escape of the encapsulates in Tf-L equipped with Chol-GALA can be attributed to pH-dependent membrane fusion. With GALA present on the surface, intracellular trafficking of liposomes after receptor-mediated endocytosis could be successfully controlled.