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.

Smad4 and p53 synergize in suppressing autochthonous intestinal cancer.

BACKGROUND: Smad4 and p53 mutations are the most common mutations in human colorectal cancers (CRCs). We evaluated whether and how they are synergistic in intestinal carcinogenesis using novel autochthonous mouse models. METHOD: To recapitulate human CRCs, we generated Villin-Cre;Smad4F / F ;Trp53F / F mice. We then compared the intestinal phenotype of Villin-Cre;Smad4F / F ;Trp53F / F mice (n = 40) with Villin-Cre;Smad4F / F (n = 30) and Villin-Cre;Trp53F / F mice (n = 45). RESULTS: Twenty-week-old Villin-Cre;Smad4F / F ;Trp53F / F mice displayed spontaneous highly proliferative intestinal tumors, and 85% of mice developed adenocarcinomas. p21 was downregulated in the intestinal mucosa in Villin-Cre;Smad4F / F ;Trp53F / F mice than in Villin-Cre;Smad4F / F and Villin-Cre;Trp53F / F mice. Villin-Cre;Smad4F / F ;Trp53F / F mice displayed multistep intestinal tumorigenesis and Wnt activation. Long-term CWP232291 (small-molecule Wnt inhibitor) treatment of Villin-Cre;Smad4F / F ;Trp53F / F mice suppressed intestinal tumorigenesis and progression. CWP232291 treatment downregulated cancer stem cell (CSC) tumor markers including CD133, Lgr-5, and Sca-1. CWP232291 treatment reduced the CSC frequency. Small-molecule Wnt inhibitors reduced intestinal CSC populations and inhibited their growth, along with Bcl-XL downregulation. Furthermore, BH3I-1, a Bcl-XL antagonist, increasingly inhibited intestinal CSCs than bulk tumor cells. CONCLUSION: Smad4 loss and p53 loss are synergistic in autochthonous intestinal carcinogenesis, by downregulating p21 and activating Wnt/ß-catenin pathway.

MiR-30a and miR-200c differentiate cholangiocarcinomas from gastrointestinal cancer liver metastases.

Prior studies have demonstrated the utility of microRNA assays for predicting some cancer tissue origins, but these assays need to be further optimized for predicting the tissue origins of adenocarcinomas of the liver. We performed microRNA profiling on 195 frozen primary tumor samples using 14 types of tumors that were either adenocarcinomas or differentiated from adenocarcinomas. The 1-nearest neighbor method predicted tissue-of-origin in 33 samples of a test set, with an accuracy of 93.9% at feature selection p values ranging from 10-4 to 10-10. According to binary decision tree analyses, the overexpression of miR-30a and the underexpression of miR-200 family members (miR-200c and miR-141) differentiated intrahepatic cholangiocarcinomas from extrahepatic adenocarcinomas. When binary decision tree analyses were performed using the test set, the prediction accuracy was 84.8%. The overexpression of miR-30a and the reduced expressions of miR-200c, miR-141, and miR-425 could distinguish intrahepatic cholangiocarcinomas from liver metastases from the gastrointestinal tract.

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.

RhoGAP domain-containing fusions and PPAPDC1A fusions are recurrent and prognostic in diffuse gastric cancer.

We conducted an RNA sequencing study to identify novel gene fusions in 80 discovery dataset tumors collected from young patients with diffuse gastric cancer (DGC). Twenty-five in-frame fusions are associated with DGC, three of which (CLDN18-ARHGAP26, CTNND1-ARHGAP26, and ANXA2-MYO9A) are recurrent in 384 DGCs based on RT-PCR. All three fusions contain a RhoGAP domain in their 3' partner genes. Patients with one of these three fusions have a significantly worse prognosis than those without. Ectopic expression of CLDN18-ARHGAP26 promotes the migration and invasion capacities of DGC cells. Parallel targeted RNA sequencing analysis additionally identifies TACC2-PPAPDC1A as a recurrent and poor prognostic in-frame fusion. Overall, PPAPDC1A fusions and in-frame fusions containing a RhoGAP domain clearly define the aggressive subset (7.5%) of DGCs, and their prognostic impact is greater than, and independent of, chromosomal instability and CDH1 mutations. Our study may provide novel genomic insights guiding future strategies for managing DGCs.

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.