In vivo specific delivery of c-Met siRNA to glioblastoma using cationic solid lipid nanoparticles

RNA interference is a powerful strategy that inhibits gene expression through specific mRNA degradation. In vivo, however, the application of small interfering RNAs (siRNAs) is severely limited by their instability and their poor delivery into target cells and tissues. This is especially true with glioblastomas (GBMs), the most frequent and malignant form of brain tumor, that has limited treatment options due to the largely impenetrable blood-brain barrier. Here, cationic solid lipid nanoparticles (SLN), reconstituted from natural components of protein-free low-density lipoprotein, was conjugated to PEGylated c-Met siRNA. The c-Met siRNA-PEG/SLN complex efficiently down-regulated c-Met expression level, as well as decreased cell proliferation in U-87MG in vitro. In orthotopic U-87MG xenograft tumor model, intravenous administration of the complex significantly inhibited c-Met expression at the tumor tissue and suppressed tumor growth without showing any systemic toxicity in mice. Use of Cy5.5 conjugated SLN revealed enhanced accumulation of the siRNA-PEG/SLN complexes specifically in the brain tumor. Our data demonstrates the feasibility of using siRNA-PEG/SLN complexes as a potential carrier of therapeutic siRNAs for the systemic treatment of GBM in the clinic.     

Clustered magnetite nanocrystals cross-linked with PEI for efficient siRNA delivery

Magnetofection has been utilized as a powerful tool to enhance gene transfection efficiency via magnetic field-enforced cellular transport processes. The accelerated accumulation of nucleic acid molecules by applying an external magnetic force enables the rapid and improved transduction efficiency. In this study, we developed magnetite nanocrystal clusters (PMNCs) cross-linked with polyethylenimine (PEI) to magnetically trigger intracellular delivery of small interfering RNA (siRNA). PMNCs were produced by cross-linked assembly of catechol-functionalized branched polyethylenimine (bPEI) around magnetite nanocrystals through an oil-in-water (O/W) emulsion and solvent evaporation method. The physical properties of PMNC were characterized by TEM, DLS, TSA, and FT-IR. Finely tuned formulation of clustered magnetite nanocrystals with controlled size and shape exhibited superior saturation of magnetization value. Magnetite nanocrystal clusters could form nanosized polyelectrolyte complexes with negatively charged siRNA molecules, enabling efficient delivery of siRNA into cells upon exposure to an external magnetic field within a short time. This study introduces a new class of magnetic nanomaterials that can be utilized for magnetically driven intracellular siRNA delivery.     

In situ forming and rutin-releasing chitosan hydrogels as injectable dressings for dermal wound healing

An in situ gel-forming system composed of rutin- and tyramine-conjugated chitosan derivatives, horseradish peroxidase (HRP), and hydrogen peroxide (H(2)O(2)) was prepared and applied to dermal wound repair. Rutin was employed to enhance production and accumulation of extracellular matrix in the healing process. In vitro study demonstrates that released rutin significantly enhanced cell proliferation as compared with media without rutin. In vivo wound healing study was performed by injecting hydrogels on rat dorsal wounds with a diameter of 8 mm for 14 days. Histological results demonstrated that rutin-conjugated hydrogel exhibited enhancement of wound healing as compared with treatments with PBS, hydrogel without rutin, and a commercialized wound dressing (Duoderm). More specifically, rutin-conjugated hydrogels induced better defined formation of neo-epithelium and thicker granulation, which is closer to the original epithelial tissue. As a result, this study suggests that the in situ gel-forming system can be a promising injectable gel-type wound dressing.     

SIDECAR POLLEN suggests a plant-specific regulatory network underlying asymmetric microspore division in Arabidopsis

Asymmetric cell division is a universal strategy to generate diverse cell types necessary for patterning and proliferation of all eukaryotes. The development of haploid male gametophytes (pollen grains) in flowering plants is a remarkable example in which division asymmetry governs the functional specialization and germline differentiation essential for double fertilization. The male gametophyte is patterned via two mitotic divisions resulting in three highly differentiated daughter cells at maturity, a vegetative cell and two sperm cells. The first asymmetric division segregates a unique male germ cell from an undetermined haploid microspore and is executed in an elaborate sequence of cellular events. However the molecular mechanisms governing the division asymmetry in microspores are poorly understood. Recently we studied the phenotype of sidecar pollen (scp) mutants in detail, and demonstrated a requirement of SCP for both the correct timing and orientation of microspore division. SCP is a microspore-specific member of the LOB/AS2 domain family (LBD27/ASL29) showing that a plant-specific regulator plays a key role in oriented division of polarized microspores. Identification of SCP will serve as a new platform to further explore the largely unknown molecular networks regulating division asymmetry in microspores that establishes the male germline in flowering plants.Key words: sidecar pollen, microspore division, division asymmetry, male gametophyte development, male germline, LBD/ASL family proteinUnlike animals, flowering plants do not set aside a distinct germline from an early stage of the life cycle. Instead the angiosperm germline or germ cells are only segregated in the male and female gametophytes by a limited number of post-meiotic mitoses.¹ However, in common with their metazoan cousins, angiosperms utilize division asymmetry for cellular patterning and differentiation of their germlines. Through the unique patterning of a ‘cell-within-a-cell’ structure with three highly differentiated cells, the male gametophyte (pollen grains) serves its biological role to deliver two sessile male gametes to the female gametophyte. Two sequential but different modes of mitotic divisions pattern the male gametophyte (Fig. 1).² The first division (of the microspore) is asymmetric giving rise to two completely different daughter cells, a larger vegetative cell that will form the pollen tube and a smaller germ cell that is engulfed within the vegetative cell cytoplasm. The second division (of the germ cell) usually appears symmetric^† and produces a pair of linked sperm cells. Microspores artificially induced to undergo symmetric division using microtubule inhibitors lack the germ cell and fail to form the typical three-celled structure showing that asymmetry in microspore division is critical for patterning of the male gametophyte.⁴Open in a separate windowFigure 1Male gametophyte development in Arabidopsis (upper part) and mutations that block germ cell formation (lower part). (Upper part) Male gametophyte development involves two rounds of mitotic division. Prior to the first division the centrally positioned microspore nucleus migrates towards the radial wall (the future germ cell pole marked with an asterisk). At this eccentric site the polarized microspores undergo oriented mitosis and cytokinesis giving rise to highly unequal daughter cells, a vegetative cell and a germ cell of which the later produces a pair of sperm cells by symmetric division. (Lower part) Mutants that fail to establish a distinct germ cell arising from specific defects are illustrated. Arrows in red indicate the developmental origin of the phenotypic defects in mutants. Note that two daughter nuclei in the mutants are in grey to show that their cell fates have not yet been thoroughly investigated. n, nucleus; Vn, vegetative nucleus; Gn, generative nucleus; Gc, generative (or germ) cell; Sc, sperm cell; WT, wild type; gem1, gemini pollen1; scp, sidecar pollen; tio, two-in-one; hik/tes, hinkel/tetraspore 12a/12b, kinesin-12a/kinesin-12b.     

Potential agents for cancer and obesity treatment with herbal medicines from the green garden

Many classes of bioactive drug-like molecules derived from traditional herbal plants are becoming attractive as alternative medicines for the treatment of severe chronic diseases such as cancer and obesity. A set of chemically synthesized drugs that is capable of both inhibiting cancer growth and reducing body weight for treatment of obesity have severe side effects including nausea, vomiting, diarrhea as well as producing increased blood pressure and headache, respectively. For decades, drug candidates from herbal plants have been considered as potential therapeutic agents because they are generally safer, less toxic, and have fewer lethal side effects than chemically synthesized or semi-synthetic drugs. Understanding the key factors affecting pharmacological effects and clinical outcomes has been a critical theme of natural product research. However, standardized sample preparation methods, well-controlled scientific studies, and validation studies are needed before herbal therapeutics can be introduced into the global market. This review will address the current advances in using traditional herbal plants, including the pharmacological effects and the challenges faced during the development of new drugs. The safety issues associated with toxicity and the effectiveness of the herbs in specific diseases such as cancer and obesity are also discussed.     

The Protective Effect of ENA Actimineral Resource A on CCl4-Induced Liver Injury in Rats

ENA Actimineral Resource A (ENA-A) is alkaline water that is composed of refined edible cuttlefish bone and two different species of seaweed, Phymatolithon calcareum and Lithothamnion corallioides. In the present study, ENA-A was investigated as an antioxidant to protect against CCl(4)-induced oxidative stress and hepatotoxicity in rats. Liver injury was induced by either subacute or chronic CCl(4) administration, and the rats had free access to tap water mixed with 0% (control group) or 10% (v/v) ENA-A for 5 or 8?weeks. The results of histological examination and measurement of antioxidant activity showed that the reactive oxygen species production, lipid peroxidation, induction of CYP2E1 were decreased and the antioxidant activity, including glutathione and catalase production, was increased in the ENA-A groups as compared with the control group. On 2-DE gel analysis of the proteomes, 13 differentially expressed proteins were obtained in the ENA-A groups as compared with the control group. Antioxidant proteins, including glutathione S-transferase, kelch-like ECH-associated protein 1, and peroxiredoxin 1, were increased with hepatocyte nuclear factor 3-beta and serum albumin precursor, and kininogen precursor decreased more in the ENA-A groups than compared to the control group. In conclusion, our results suggest that ENA-A does indeed have some protective capabilities against CCl(4)-induced liver injury through its antioxidant function.     

Levosulpiride, (S)-(-)-5-Aminosulfonyl-N-[(1-ethyl-2-pyrrolidinyl) methyl]-2-methoxybenzamide, enhances the transduction efficiency of PEP-1-ribosomal protein S3 in vitro and in vivo

Many proteins with poor transduction efficiency were reported to be delivered to cells by fusion with protein transduction domains (PTDs). In this study, we investigated the effect of levosulpiride on the transduction of PEP-1 ribosomal protein S3 (PEP-1-rpS3), and examined its influence on the stimulation of the therapeutic properties of PEP-1-rpS3. PEP-1-rpS3 transduction into HaCaT human keratinocytes and mouse skin was stimulated by levosulpiride in a manner that did not directly affect the cell viability. Following 12-O-tetradecanoylphorbol- 13-acetate (TPA)-induced inflammation in mice, levosulpiride alone was ineffective in reducing TPA-induced edema and in inhibiting the elevated productions of inflammatory mediators and cytokines, such as cyclooxygenase-2, inducible nitric oxide synthase, interleukin-6 and -1β, and tumor necrosis factor- α. Anti-inflammatory activity by PEP-1-rpS3 + levosulpiride was significantly more potent than by PEP-1-rpS3 alone. These results suggest that levosulpiride may be useful for enhancing the therapeutic effect of PEP-1-rpS3 against various inflammatory diseases. [BMB reports 2011; 44(5): 329-334].     

Glucocorticoid receptor (GR)-associated SMRT binding to C/EBPbeta TAD and Nrf2 Neh4/5: role of SMRT recruited to GR in GSTA2 gene repression

The expression of the glutathione S-transferase gene (GST), whose induction accounts for cancer chemoprevention, is regulated by activation of CCAAT/enhancer binding protein beta (C/EBPbeta) and NF-E2-related factor 2 (Nrf2). The present study investigated the repressing effects of activating glucocorticoid receptor (GR) on C/EBPbeta- and Nrf2-mediated GSTA2 gene induction and the mechanism. Dexamethasone that activates GR inhibited constitutive and oltipraz- or tert-butylhydroquinone (t-BHQ)-inducible GSTA2 expression in H4IIE cells. Also, dexamethasone repressed GSTA2 promoter-luciferase gene activity. Dexamethasone-GR activation did not inhibit nuclear translocation of C/EBPbeta or Nrf2 nor their DNA binding activities induced by oltipraz or t-BHQ. Deletion of the glucocorticoid response element (GRE) in the GSTA2 promoter abolished dexamethasone inhibition of the gene induction. Immunoprecipitation-immunoblotting, chromatin immunoprecipitation, and GST pull-down assays revealed that silencing mediator for retinoid and thyroid hormone receptors (SMRT), a corepressor recruited to steroid-GR complex for histone deacetylation, bound to TAD domain of C/EBPbeta and Neh4/5 domain of Nrf2. The GSTA2 promoter-luciferase activities were decreased by SMRT but not by truncated SMRTs. The small interference RNA (siRNA) against SMRT abolished SMRT repression of the gene induction by C/EBPbeta or Nrf2. The plasmid transfection and siRNA experiments directly evidenced the functional role of SMRT in GSTA2 repression. In conclusion, dexamethasone antagonizes C/EBPbeta- and Nrf2-mediated GSTA2 gene induction via ligand-GR binding to the GRE, and steroid-mediated GSTA2 repression involves inactivation of C/EBPbeta and Nrf2 by SMRT recruited to steroid-GR complex.     

Desensitization of canonical transient receptor potential channel 5 by protein kinase C

The classic type of transient receptor potential channel (TRPC) is a molecular candidate for Ca(2+)-permeable cation channel in mammalian cells. TRPC5 is desensitized rapidly after activation by G protein-coupled receptor. Herein we report our investigation into the desensitization of mTRPC5 and localization of the molecular determinants of this desensitization using mutagenesis. TRPC5 was initially activated by muscarinic stimulation using 100 microM carbachol (CCh) and then decayed rapidly even in the presence of CCh (desensitization). Increased EGTA or omission of MgATP in the pipette solution slowed the rate of this desensitization. The protein kinase C (PKC) inhibitors, 1 microM chelerythrine, 100 nM GF109203X, or PKC peptide inhibitor (19-36), inhibited this desensitization of TRPC5 activated by 100 microM CCh. When TRPC5 current was activated by intracellular GTPgammaS, PKC inhibitors prevented TRPC5 desensitization and the mutation of TRPC5 T972 to alanine slowed the desensitization process dramatically. We conclude that the desensitization of TRPC5 occurs via PKC phosphorylation and suggest that threonine at residue 972 of mouse TRPC5 might be required for its phosphorylation by PKC.