Efficient gene transfection to lung cancer cells via Folate-PEI-Sorbitol gene transporter.

Lung cancer is known to be one of the fatal diseases in the world and is experiencing treatment difficulties. Many treatments have been discovered and implemented, but death rate of patients with lung cancer continues to remain high. Current treatments for cancer such as chemotherapy, immunotherapy, and radiotherapy have shown considerable results, yet they are accompanied by side effects. One effective method for reducing the cytotoxicity of these treatments is via the use of a nanoparticle-mediated siRNA delivery strategy with selective silencing effects and non-viral vectors. In this study, a folate (FA) moiety ligand-conjugated poly(sorbitol-co-PEI)-based gene transporter was designed by combining low-molecular weight polyethyleneimine (LMW PEI) and D-sorbitol with FA to form FPS. Since folate receptors are commonly overexpressed in various cancer cells, folate-conjugated nanoparticles may be more effectively delivered to selective cancer cells. Additionally, siOPA1 was used to induce apoptosis through mitochondrial fusion. The OPA1 protein stability level is important for maintaining normal mitochondrial cristae structure and function, conserving the inner membrane structure, and protecting cells from apoptosis. Consequently, when FPS/siOPA1 was used for lung cancer in-vitro and in-vivo, it improved cell viability and cellular uptake.

Development of novel, biocompatible, polyester amines for microglia-targeting gene delivery.

Recent progress in personalized medicine and gene delivery has created exciting opportunities in therapeutics for central nervous system (CNS) disorders. Despite the interest in gene-based therapies, successful delivery of nucleic acids for treatment of CNS disorders faces major challenges. Here we report the facile synthesis of a novel, biodegradable, microglia-targeting polyester amine (PEA) carrier based on hydrophilic triethylene glycol dimethacrylate (TG) and low-molecular weight polyethylenimine (LMW-PEI). This nanocarrier, TG-branched PEI (TGP), successfully condensed double-stranded DNA into a size smaller than 200 nm. TGP nanoplexes were nontoxic in primary mixed glial cells and showed elevated transfection efficiency compared with PEI-25K and lipofector-EZ. After intrathecal and intracranial administration, PEA nanoplexes delivered genes specifically to microglia in the spinal cord and brain, respectively, proposing TGP as a novel microglia-specific gene delivery nanocarrier. The microglia-specific targeting of the TGP nanocarrier offers a new therapeutic strategy to modulate CNS disorders involving aberrant microglia activation while minimizing off-target side effects.

Insights of tankyrases: A novel target for drug discovery.

Tankyrases are the group of enzymes belonging to a class of Poly (ADP-ribose) polymerase (PARP) recently named ADP-ribosyltransferase (ARTD). The two isoforms of tankyrase i.e. tankyrase1 (TNKS1) and tankyrase2 (TNKS2) were abundantly expressed in various biological functions in telomere regulation, Wnt/ß-catenin signaling pathway, viral replication, endogenous hormone regulation, glucose transport, cherubism disease, erectile dysfunction, and apoptosis. The structural analysis, mechanistic information, in vitro and in vivo studies led identification and development of several classes of tankyrase inhibitors under clinical phases. In the nutshell, this review will drive future research on tankyrase as it enlighten the structural and functional features of TNKS 1 and TNKS 2, different classes of inhibitors with their structure-activity relationship studies, molecular modeling studies, as well as past, current and future perspective of the different class of tankyrase inhibitors.

Sugar alcohol-based polymeric gene carriers: Synthesis, properties and gene therapy applications.

Advances in the field of nanomedicine have led to the development of various gene carriers with desirable cellular responses. However, unfavorable stability and physicochemical properties have hindered their applications in vivo. Therefore, multifunctional, smart nanocarriers with unique properties to overcome such drawbacks are needed. Among them, sugar alcohol-based nanoparticle with abundant surface chemistry, numerous hydroxyl groups, acceptable biocompatibility and biodegradable property are considered as the recent additions to the growing list of non-viral vectors. In this review, we present some of the major advances in our laboratory in developing sugar-based polymers as non-viral gene delivery vectors to treat various diseases. We also discuss some of the open questions in this field. STATEMENT OF SIGNIFICANCE: Recently, the development of sugar alcohol-based polymers conjugated with polyethylenimine (PEI) has attracted tremendous interest as gene delivery vectors. First, the natural backbone of polymers with their numerous hydroxyl groups display a wide range of hyperosmotic properties and can thereby enhance the cellular uptake of genetic materials via receptor-mediated endocytosis. Second, conjugation of a PEI backbone with sugar alcohols via Michael addition contributes to buffering capacity and thereby the proton sponge effect. Last, sugar alcohol based gene delivery systems improves therapeutic efficacy both in vitro and in vivo.

Biodegradable Polymeric Nanocarrier-Based Immunotherapy in Hepatitis Vaccination.

Various commercial vaccines are used for immunization against hepatitis B. However, these immunotherapeutic vaccines require invasive administration, which can induce side effects, and require multiple shots to elicit an immune response, limiting their efficacy. Compared to traditional hepatitis B vaccines, polymer nanoparticles have more advantageous inherent properties as vaccine delivery carriers, providing increased stability of encapsulated antigen, the possibility of single-shot immunotherapy, and the capability of mucosal administration, which allows various routes of vaccination. In this review, we present up-to-date information on the potential of a biodegradable nanoparticle-based delivery system in treating hepatitis B. We also discuss the application of nanoparticles in various vaccines and highlighted strategies for eliciting an appropriate immune response.

Targeted Delivery of siRNA Therapeutics using Ligand Mediated Biodegradable Polymeric Nanocarriers.

BACKGROUND: Cancer poses a major public health issue, is linked with high mortality rates across the world, and shows a strong interplay between genetic and environmental factors. To date, common therapeutics, including chemotherapy, immunotherapy, and radiotherapy, have made significant contributions to cancer treatment, although diverse obstacles for achieving the permanent "magic bullet" cure have remained. Recently, various anticancer therapeutic agents designed to overcome the limitations of these conventional cancer treatments have received considerable attention. One of these promising and novel agents is the siRNA delivery system; however, poor cellular uptake and altered siRNA stability in physiological environments have limited its use in clinical trials. Therefore, developing the ideal siRNA delivery system with low cytotoxicity, improved siRNA stability in the body's circulation, and prevention of its rapid clearance from bodily fluids, is rapidly emerging as an innovative therapeutic strategy to combat cancer. Moreover, active targeting using ligand moieties which bind to over-expressed receptors on the surface of cancer cells would enhance the therapeutic efficiency of siRNA. CONCLUSION: In this review, we provide 1) an overview of the non-viral carrier associated with siRNA delivery for cancer treatment, and 2) a description of the five major cancer-targeting ligands.

Sugar-based gene delivery systems: Current knowledge and new perspectives.

Carbohydrates, one of the most abundant natural compounds and key participants in many biological processes, are relevant in medical and industrial fields. In comparison with synthetic polymers, carbohydrates are biocompatible and have intrinsic targeting properties, enabling them to interact with cell-surface receptors. Among the different carbohydrates, polysaccharides are naturally occurring biological molecules with tremendous potential for biomedical applications. The physicochemical properties of these polysaccharide based nanoparticles, such as excellent biocompatibility, surface charge to interact with nucleic acids, low toxicity and cost effectiveness make them superior carriers for nanomedicine. In addition to variety of physicochemical properties, polysaccharides allow the great ease of chemical modification which enables the preparation of wide range of nanoparticles. In this review, we present the state-of-the-art information on the potential of polysaccharides-based polymers as non-viral gene delivery vectors in treating various diseases. Then, we discuss the chemical modification and structure/property relationship of carbohydrates.

Biphenyl tetrazole-thiazolidinediones as novel bacterial peptide deformylase inhibitors: Synthesis, biological evaluations and molecular docking study.

Herein, we report the synthesis and screening of biphenyl tetrazole-thiazolidinediones 14(a-j) as bacterial Peptide deformylase (PDF) enzyme inhibitors. The compounds 14b (IC50 value=16.25µM), 14c (IC50 value=18.00µM) and 14h (IC50 value=17.25µM) had shown good PDF inhibition activity. The compounds 14b (MIC range=20.75-35.41µg/mL), 14c (MIC range=19.41-26.00µg/mL) and 14d (MIC range=8.41-8.58µg/mL) had also shown potent antibacterial activity when compared with standard ciprofloxacin (MIC range=25-50µg/mL). Thus, the active derivatives were not only potent PDF inhibitors but also efficient antibacterial agents. In order to gain more insight on the binding mode of the compounds with PDF enzyme, the synthesized compounds 14(a-j) were docked against PDF enzyme of E. coli and compounds exhibited good binding properties. The results suggest that this class of compounds have been potential for development and use in a future as antibacterial drugs.

Efficient gene transfection to liver cells via the cellular regulation of a multifunctional polylactitol-based gene transporter.

In recent years, the introduction of non-viral gene transfer systems for the treatment of inherited and acquired liver diseases has attracted a lot of attention. To facilitate liver-directed gene delivery, a liver cell targeting strategy and a intracellular control of gene trafficking for the design of an ideal non-viral gene delivery system are crucial and a great challenge. In order to meet these needs, a new multifunctional gene carrier, the polylactitol-based gene transporter (PLT), was prepared by crosslinking low molecular weight polyethylenimine (LMW PEI) with lactitol diacrylate (LDA) composed of d-galactose and d-sorbitol. These provide synergistic effects that increase cellular uptake, result in liver cell targeting and a rapid release of the gene from the endosome, because the hyperosmotic property of the polysorbitol part selectively stimulates caveolae-mediated endocytosis, the polygalactose part provides liver cell targeting ability and the PEI part assists in the rapid endosomal escape of the gene due to its proton sponge effect. With these unique multifunctions, PLT/DNA nanocomplexes showed low cytotoxicity, high transfection efficiency, liver cell targeting in vitro and in vivo, and a selective transition of the cellular uptake pathway into the caveolae-mediated endocytosis avoiding lysosomal degradation. PLT was confirmed as a safe and efficient vector, highlighting a potential candidate for targeted gene therapy in hepatic diseases.

Correction: Efficient gene transfection to liver cells via the cellular regulation of a multifunctional polylactitol-based gene transporter.

Correction for 'Efficient gene transfection to liver cells via the cellular regulation of a multifunctional polylactitol-based gene transporter' by Young-Dong Kim et al., J. Mater. Chem. B, 2016, 4, 2208-2218.

Image-Guided Nanoparticle-Based siRNA Delivery for Cancer Therapy.

With the discovery of RNA interference technology, small-interfering RNA (siRNA) has emerged as new powerful tool for gene therapy because of its high targeting specificity and selectivity. However, one of the limitations to successful gene therapy is the inability to monitor delivery of genes and therapeutic responses at the targeted site. Hence, a combinatorial approach of gene therapy with molecular imaging has been crucial in optimizing gene therapy. Recent advances in nanotechnology have made tremendous efforts to develop multifunctional nanoparticles that contain imaging and therapeutic agents together for image-guided therapy. The nanoparticles serve as contrast agents in imaging for disease detection with simultaneous delivery of therapeutics to cure the diseases. The therapy also helps to monitor the drug accumulation and assimilation in the body, thereby facilitating the evaluation of treatment effects. Here, we present an overview of polymer and lipid-based carriers for siRNA delivery, along with imaging agents as image guided therapy, in the treatment of breast, lung, liver, ovarian, cervical, and prostate cancers.

Nanoparticle-mediated delivery of siRNA for effective lung cancer therapy.

Lung cancer is one of the most lethal diseases worldwide, and the survival rate is less than 15% even after the treatment. Unfortunately, chemotherapeutic treatments for lung cancer are accompanied by severe side effects, lack of selectivity and multidrug resistance. In order to overcome the limitations of conventional chemotherapy, nanoparticle-mediated RNA interference drugs represent a potential new approach due to selective silencing effect of oncogenes and multidrug resistance related genes. In this review, we provide recent advancements on nanoparticle-mediated siRNA delivery strategies including lipid system, polymeric system and rigid nanoparticles for lung cancer therapies. Importantly, codelivery of siRNA with conventional anticancer drugs and recent theranostic agents that offer great potential for lung cancer therapy is covered.

Mucoadhesive and pH-sensitive thiolated Eudragit microspheres for oral delivery of Pasteurella multocida antigens containing dermonecrotoxin.

In this study, cysteine was conjugated to the Eudragit to have mucoadhesive and pH-sensitive properties. Pasteurella multocida dermonecrotoxin (PMT) is a major virulence factor as a causative agent of atrophic rhinitis (AR) in swine and, therefore, inactivated P. multocida was used as a candidate vaccine in the current study. PMT-loaded thiolated Eudragit microspheres (TEMS) prepared using W/O/W emulsion-solvent evaporation method were characterized to assess their efficacy in oral vaccination. PMT-loaded TEMS were observed as spherical shapes with smooth surfaces and average particle sizes were 5.2 +/- 0.55 microm. The loading efficiency of PMT in the TEMS was about 75.3%. A significantly higher percentage of PMT from PMT-loaded TEMS was released at pH 7.4 than at pH 1.5. Murine macrophage stimulated with PMT-loaded TEMS facilitated a gradual secretion of tumor necrosis factor-alpha and nitric oxide as immune stimulatory mediators in a time dependent manner, suggesting that the released PMT from PMT-loaded TEMS had immune stimulating activity of AR vaccine in vitro.

Degradable poly(amido amine)s as gene delivery carriers.

INTRODUCTION: In recent years, there has been a great deal of interest in the development of vectors which are being developed based on the capacity of polymers to mediate appropriate interactions with the cellular environment, or to interface with specific cellular processes. Several such vectors have been synthesized, resulting in biomacromolecules with low cytotoxicity and higher gene delivery ability. AREAS COVERED: This review briefly describes the recent success of poly(amido amine)s (PAAs) as non-viral vectors, and highlights their promising future in the development of nucleic acid-based therapy. It also provides an overview on the synthesis, characterization and application of PAAs as gene carriers, which will be useful for various biological motifs. This review helps the readers to better understand the emergence of non-viral vectors for gene therapy, especially PAAs, their properties, their advantages and disadvantages and the gene therapy based on them. EXPERT OPINION: The future of gene-based therapy needs to identify approaches to develop new carriers, depending on the properties of the biological membranes they face, and their physicochemical properties, in order to successfully deliver the genes to the target sites. With the emergence of a variety of non-viral vectors, such as biodegradable polymers, it may not take long before non-viral vectors are observed that are not just safe and tissue-specific, but even more efficient than viral vectors.

Folate conjugated poly(ester amine) for lung cancer therapy.

Folate conjugated poly(ester amine) (PEA) was prepared by reaction of folic acid with PEAs based on polycaprolactone (PCL) and low molecular weight polyethylenimine (LMW-PEI) with PEG as a linker. This novel gene carrier showed excellent physicochemical properties and relatively low cytotoxicity compared with PEI 25K. It showed excellent transfection efficiency through folate receptor mediated endocytosis.

pH-Responsive Polymers as Gene Carriers.

Despite the immense potential of non-viral delivery system in gene therapy its application has been impaired greatly by various impediments having contrasting traits. Therefore it is an absolute necessity to develop some non-viral vectors which are endowed with special characteristics to act differently in intracellular as well as extracellular compartments to surmount these inter-conflicting hurdles. Such smart polymers should serve some specific purposes by adjusting their structural or functional traits under the influence of stimuli such as temperature, light, salt concentration or pH. Among all these stimuli-responsive polymers pH-responsive polymers have attracted major attention and great impetus has been directed towards utilizing the subtle yet significant change in pH value within the cellular compartments. This review is intended to provide a comprehensive account of the development of pH-responsive polymeric vectors based on their structural features and consequent functional attributes to achieve efficient transfection. The underlying modes of actions relating to structure and differential pH environment have also been discussed in this review.

The therapeutic efficiency of FP-PEA/TAM67 gene complexes via folate receptor-mediated endocytosis in a xenograft mice model.

To circumvent carrier related obstacles, we developed a biodegradable, folate conjugated poly (ester amine) (FP-PEA) that mediates high level folate receptor (FR) mediated endocytosis in vitro as well as in vivo. We report the efficacy of a therapeutic strategy that combines the potency of FP-PEA based on polycaprolactone (PCL) and low molecular weight polyethylenimine (LMW-PEI) with the tumor targeting potential of receptor mediated endocytosis. When tested on cells in culture, FP-PEA was found to retain high affinity for FR-positive cells compared with PEA without folate moiety (P-PEA). The FR specific activity of FP-PEA was drastically decreased in the presence of an excess free folic acid and very less significant transfection was detected against FR-negative cells. FP-PEA showed marked anti-tumor activity against FR-positive human KB tumors in nude mice with no evidence of toxicity during and after therapy using TAM67 gene. Furthermore, the therapeutic effect occurred in the apparent absence of weight loss or noticeable tumor apoptosis. In contrast, no significant anti-tumor activity was observed in P-PEA treated mice which were co dosed with an excess of FR, thus demonstrating the target specific gene delivery. Furthermore, anti-tumor activity with PEA without folic acid moiety (P-PEA) proved not to be effective against xenograft mice model with KB cells when administered at the same dose to that of FP-PEA. Taken together, these results indicate that FP-PEA is highly effective gene carrier capable of producing therapeutic benefit in xenograft mice model without any sign of toxicity.

Efficient gene delivery with osmotically active and hyperbranched poly(ester amine)s.

Degradable and hyperbranched poly (ester amine)s (PEAs) were successfully synthesized by Michael addition reaction between hydrophilic glycerol triacrylate (GTA) and low-molecular-weight polyethylenimine (LMW-PEI) and evaluated as nonviral gene carriers. PEAs effectively condensed DNA with particle sizes below 200 nm and suitable surface charges (15-45 mV), suitable for intracellular delivery. PEAs degraded in a controlled fashion showing half-lives of more than 12 days and were essentially nontoxic in three different cell lines. Elevated transfection levels by luciferase assay revealed the superiority of PEAs over PEI 25K and Lipofectamine. PEAs synthesized using 1:4 mol ratio of GTA to PEI [GTA/PEI-1.2(1:4)] showed highest transfection efficiency in HepG2 cells. PEAs showed significant gene expression in vitro as well as in vivo through aerosol administration. Reduction in packed cell volume (PCV) of cells when treated with polyplexes supported the hyperosmotic effect of PEAs. Effect of bafilomycin A1 on transfection efficiency of PEAs on 293T cells indicated its endosomal buffering capacity. High transfection efficiency was attributed to the synergism from hyperosmotic glycerol backbone in the PEAs and endosomal buffering capacity of PEI amine groups. Therefore, this convergence of osmotically active biodegradable PEAs suggests their potential as a safe and efficient gene delivery vector.

Biodegradable poly(ester amine)s for gene delivery applications.

Cationic polymers have been increasingly proposed as potential gene delivery vectors because of their versatility. In this paper, we focus on the characteristics of poly(ester amine)s (PEAs) as gene delivery carriers, degradation pattern as an essential parameter for reduced toxicity, classification based on its physicochemical properties followed by its success as efficient gene delivery carrier in vitro and in vivo. We also discuss the conjugation of ligands/charged groups to the side chain of the polyester in order to achieve receptor-mediated endocytosis as well as target-specific delivery of DNA. Capable of delivering exogenous genes to a cell nucleus, these cationic PEAs also serve as a valuable model to understand the important characteristics that render a polymer an effective gene carrier.

Biodegradable poly(ester amine) based on glycerol dimethacrylate and polyethylenimine as a gene carrier.

BACKGROUND: Polyethylenimine (PEI) vectors are widely used in gene delivery because of their high transfection efficiency owing to a unique proton sponge effect. An increase in molecular weight increases transfection efficiency, but simultaneously results in increased toxicity. Therefore, the design and synthesis of new degradable gene delivery carriers having high transfection efficiencies and reduced cytotoxicity are necessary. METHODS: In the present study degradable poly(ester amines) (PEAs) based on glycerol dimethacrylate (GDM) and low molecular weight branched polyethylenimine (LMW-PEI) were synthesized in anhydrous methanol at 60 degrees C following Michael addition reaction. The transfection efficiencies of the synthesized PEA/DNA complexes were evaluated using three different cell lines (HeLa, HepG2 and 293T cells) in vitro. RESULTS: PEAs with zeta potential in the range of 30-55 mV (at physiological pH) condensed plasmid DNA into nanosized particles (<150 nm) suitable for intracellular delivery. The PEAs degraded in a controlled fashion (t(1/2) of approximately 9-10 days). Compared with PEI 25K, the PEAs showed significantly lower cytotoxicity in three different cells. The PEAs demonstrated much higher transfection efficiency compared to conventional PEI 25K and Lipofectamine. The PEA synthesized using a 1 : 4 mole ratio of GDM to PEI [GDM/PEI-1.2 (1:4)] showed the highest transfection efficiency in HepG2 cells. Significantly higher pEGFP-N(2) reporter gene expression in 293T cells was achieved using these PEAs. The hyperosmotic effect of PEAs was demonstrated by the reduction in packed cell volume (PCV). The GDM/PEI-1.2 (1:4) showed comparable reduction in PCV with respect to glycerol in 293T cells. The effect of bafilomycin A(1) on transfection efficiency of PEAs on 293T cells indicated its endosomal buffering capacity. CONCLUSIONS: We hypothesized that the higher transfection efficiency of PEAs was the synergistic effect arising from hyperosmotic glycerol and endosomal buffering capacity of PEAs resulting from the presence of a glycerol backbone and PEI amine groups, respectively.