Anthony S. Malamas scite author profile

Small interfering RNA (siRNA) has garnered much attention in recent years as a promising avenue for cancer gene therapy due to its ability to silence disease-related genes. Effective gene silencing is contingent upon the delivery of siRNA into the cytosol of target cells and requires the implementation of delivery systems possessing multiple functionalities to overcome delivery barriers. The present work explores the multifunctional properties and biological activity of a recently developed cationic lipid carrier, (1-aminoethyl)iminobis[N-(oleicylcysteinyl-1-amino-ethyl)propionamide]) (ECO). The physicochemical properties and biological activity of ECO/siRNA nanoparticles were assessed over a range of N/P ratios to optimize the formulation. Potent and sustained luciferase silencing in a U87 glioblastoma cell line was observed, even in the presence of serum proteins. ECO/siRNA nanoparticles exhibited pH-dependent membrane disruption at pH levels corresponding to various stages of the intracellular trafficking pathway. It was found that disulfide linkages created during nanoparticle formation enhanced the protection of siRNA from degradation and facilitated site-specific siRNA release in the cytosol by glutathione-mediated reduction. Confocal microscopy confirmed that ECO/siRNA nanoparticles readily escaped from late endosomes prior to cytosolic release of the siRNA cargo. These results demonstrate that the rationally designed multifunctionality of ECO/siRNA nanoparticles is critical for intracellular siRNA delivery and the continuing development of safe and effective delivery systems.

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Design and evaluation of new pH-sensitive amphiphilic cationic lipids for siRNA delivery

Malamas

Gujrati

Kummitha

et al. 2013

Journal of Controlled Release

105

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Synthetic small interfering RNA (siRNA) has become the basis of a new generation of gene-silencing cancer therapeutics. However, successful implementation of this novel therapy relies on the ability to effectively deliver siRNA into target cells and to prevent degradation of siRNA in lysosomes after endocytosis. In this study, our goal was to design and optimize new amphiphilic cationic lipid carriers that exhibit selective pH-sensitive endosomal membrane disruptive capabilities to allow for the efficient release of their siRNA payload into the cytosol. The pH sensitive siRNA carriers consist of three domains (cationic head, hydrophobic tail, amino acid-based linker). A library of eight lipid carriers were synthesized using solid phase chemistry, and then studied to determine the role of (1) the number of protonable amines and overall pKa of the cationic head group, (2) the degree of unsaturation of the hydrophobic tail, and (3) the presence of histidine residues in the amino acid linker for transfection and silencing efficacy. In vitro screening evaluation of the new carriers demonstrated at least 80% knockdown of a GFP reporter in CHO cells after 72 hours. The carriers ECO and ECLn performed the best in a luciferase knockdown study in HT29 human colon cancer cells, which were found to be more difficult to transfect. They significantly reduced expression of this reporter to 22.7±3.31% and 23.5±5.11% after 72 hours post-transfection, better than Lipofectamine RNAiMax. Both ECO and ECLn carriers caused minimal cytotoxicity, preserving relative cell viabilities at 87.3±2.72% and 88.9±6.84%, respectively. A series of hemolysis assays at various pHs revealed that increasing the number of amines in the protonable head group, and removing the histidine residue from the linker, both resulted in improved membrane disruptive activity at the endosomal pH of 6.5. Meanwhile, the cellular uptake into HT29 cancer cells was improved, not only by increasing the amines of the head group, but also by increasing the degree of unsaturation in the lipid tails. Due to flexibility of the synthetic procedure, the delivery system could be modified further for different applications. The success of ECO and ECLn for in-vitro siRNA delivery potentially makes them promising candidates for future in-vivo studies

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Tumor Cells Surviving Exposure to Proton or Photon Radiation Share a Common Immunogenic Modulation Signature, Rendering Them More Sensitive to T Cell–Mediated Killing

Gameiro

Malamas

Bernstein

et al. 2016

International Journal of Radiation Oncology*Biology*Physics

124

102

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Purpose This study was designed to provide the foundation for combining immunotherapy to induce tumor antigen-specific T cells with proton radiation therapy to exploit the activity of those T cells. We have recently defined “immunogenic modulation,” a mechanism distinct from immunogenic cell death, whereby tumor cells surviving photon radiation therapy nonetheless become more susceptible to cytotoxic T lymphocyte (CTL)-mediated lysis. However, to our knowledge, there are no prior studies examining the role of proton radiation on tumor immune sensitivity. Materials and Methods Using cell lines of tumors frequently treated with proton radiation, such as prostate, breast, lung, and chordoma, we examined the effect of proton radiation on the viability and induction of immunogenic modulation in tumor cells by flow cytometric and immunofluorescent analysis of surface phenotype and the functional immune consequences. Results These studies show for the first time that a) proton and photon radiation induced comparable upregulation of surface molecules involved in immune recognition (HLA, ICAM-1, and the tumor-associated antigens CEA and MUC-1), b) proton radiation mediated calreticulin cell-surface expression, increasing sensitivity to cytotoxic T-lymphocyte killing of tumor cells, and c) cancer stem cells (CSCs), which are resistant to the direct cytolytic activity of proton radiation, nonetheless upregulated calreticulin after radiation in a manner similar to non-CSCs. Conclusions These findings offer a rationale for the use of proton radiation in combination with immunotherapy, including for patients who have failed radiation therapy alone or have limited treatment options.

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