Development of Long Asymmetric siRNA Structure for Target Gene Silencing and Immune Stimulation in Mammalian Cells.

Post-transcriptional regulation of transcript abundances by RNA interference (RNAi) is a widely conserved regulatory mechanism to control cellular processes. We previously introduced an alternative siRNA structure called asymmetric siRNA (asiRNA), and showed that asiRNA exhibits comparable gene-silencing efficiency with reduced off-target effects compared with conventional siRNAs. However, to what extent the length of the guide strand affects the gene-silencing efficiency of asiRNAs is still elusive. In this study, we analyzed in detail the gene-silencing ability of asiRNAs along the guide strand length and immunostimulatory capacity of asiRNAs. We generated asiRNAs containing various guide strand lengths ranging from 25 to 29 nt, called long asiRNA (lasiRNA). We found that the gene-silencing activity of lasiRNAs decreased as the length of the guide strand increased. Nonetheless, the 3'-end overhangs that are complementary to the target gene have higher efficiency for gene silencing compared with mismatched overhangs. In addition, we found that the silencing efficiency of lasiRNAs correlates with their Ago2-binding affinity. Finally, replacing the mismatched overhang with a TLR7- or TLR9-associated immune response motif induced a toll-like receptor (TLR)-specific immune response and retained gene-silencing activity. Our findings demonstrate that lasiRNA structures can be tailored to function as bifunctional siRNA, which trigger a specific immune response combined with target gene silencing. Taken together, we anticipate that our findings provide a road map for the subsequent development of immune-stimulating lasiRNA, which bear the potential to be applied for therapeutic benefits.

RIG-I-Mediated Innate Immune Stimulation by Chemically Synthesized Long Double-Stranded RNAs Is Structure and Sequence Dependent.

Double-stranded RNAs (dsRNAs) longer than 30 bp have not been considered desirable RNA interference (RNAi) triggering structures in mammalian cells as they nonspecifically activate innate immune response. However, in earlier studies, not only dsRNA length but also 5'-triphosphate moiety produced by in vitro transcription might have affected the stimulation of innate immune system. Herein, using chemically synthesized long dsRNAs without 5'-triphosphate, we elucidated direct relationship between length of dsRNAs and innate immune stimulation. First, we found that blunt-ended, chemically synthesized 38/40-60 bp-long dsRNAs induced retinoic acid-inducible gene I (RIG-I)-mediated innate immune response, which was suppressed by the introduction of the 2-nt 3' overhang structure. Surprisingly, we discovered that RIG-I activation by these long dsRNAs is also sequence dependent, and the sequence composition at dsRNA termini is important for RIG-I activation. In addition, we identified that long dsRNAs over 38 bp could elicit single- or dual-target gene silencing in a Dicer-independent manner. Taken together, our findings may serve as guidelines to develop an immunostimulatory RNAi trigger to exploit host's innate immune system, as well as a specific dual-gene targeting RNAi therapeutics platform without nonspecific innate immune stimulation by RIG-I.

L-Type Calcium Channel Blocker Enhances Cellular Delivery and Gene Silencing Potency of Cell-Penetrating Asymmetric siRNAs.

The efficient delivery of small interfering RNAs (siRNAs) to the target cells is critical for the pharmaceutical success of RNA interference (RNAi) drugs. One of the possible strategies to improve siRNA delivery is to identify auxiliary molecules that augment their cellular uptake. Herein, we performed a chemical library screening in an effort to discover small molecules that enhance the potency of cholesterol-conjugated, cell-penetrating asymmetric siRNAs (cp-asiRNAs). Interestingly, three compounds identified from the screen share a common dihydropyridine (DHP) core and function as L-type calcium channel blockers (CCBs). Using confocal microscopy and quantitative analysis of small RNAs, we demonstrated that the L-type CCBs increased the endocytic cellular uptake of cp-asiRNAs. Furthermore, these small molecules substantially improved the potency of cp-asiRNAs, not only in vitro but also in vivo on rat skin. Collectively, our study provides an alternative pharmacological approach for the identification of small molecules that potentiate the effects of therapeutic siRNAs.

ALPPL2 Is a Potential Diagnostic Biomarker for Pancreatic Cancer-Derived Extracellular Vesicles.

Pancreatic cancer is an aggressive malignancy that often goes undiagnosed in the early stages. Non-invasive, early, and accurate diagnosis is therefore undoubtedly the "holy grail" of pancreatic cancer research. However, despite extensive research efforts, there is no definitive biomarker for this cancer. Previously, we identified alkaline phosphatase placental-like 2 (ALPPL2) as a diagnostic biomarker for pancreatic ductal adenocarcinoma and developed a 2'-fluoro modified RNA aptamer toward it. In this study, we show that ALPPL2 is present in pancreatic cancer extracellular vesicles (EVs) and therefore has potential application in liquid biopsy-based diagnostic strategies. We also developed ALPPL2 direct and sandwich aptamer-linked immobilized sorbent assay (ALISA) for EVs, which could sensitively and specifically detect the protein. We believe that our ALISA format may have a potential diagnostic utility in screening pancreatic-cancer-derived EVs.

Cell-SELEX-Based Identification of a Human and Mouse Cross-Reactive Endothelial Cell-Internalizing Aptamer.

Increased interest and insights gained by researchers on the roles of endothelial cells in the pathophysiology of cancer, inflammatory, and cardiovascular diseases have led to the design of pharmacological interventions aimed at the endothelium lining in the diseased sites. Toward this end, we used established brain microvascular endothelial cell lines mouse (bEND3), human (hCMEC/D3), and Toggle Cell-SELEX to identify a species cross-reactive, endothelial cell-internalizing aptamer R11-3. This 2'F-modified RNA aptamer is specific for endothelial cells as no internalization was seen with cells of nonendothelial origin. R11-3 was truncated in size, and its potential in endothelial targeted therapeutics was established using VEGFR2 targeting long interfering RNA (liRNA) aptamer chimera. Due to its specificity for both mouse and human endothelial cells, we believe that this aptamer not only fits for development of endothelial targeted drug development for human diseases but is also suitable for preclinical evaluation in mice.

Cell-SELEX Based Identification of an RNA Aptamer for Escherichia coli and Its Use in Various Detection Formats.

Escherichia coli are important indicator organisms, used routinely for the monitoring of water and food safety. For quick, sensitive and real-time detection of E. coli we developed a 2'F modified RNA aptamer Ec3, by Cell-SELEX. The 31 nucleotide truncated Ec3 demonstrated improved binding and low nano-molar affinity to E. coli. The aptamer developed by us out-performs the commercial antibody and aptamer used for E. coli detection. Ec3(31) aptamer based E. coli detection was done using three different detection formats and the assay sensitivities were determined. Conventional Ec3(31)-biotin-streptavidin magnetic separation could detect E. coli with a limit of detection of 1.3 × 106 CFU/ml. Although, optical analytic technique, biolayer interferometry, did not improve the sensitivity of detection for whole cells, a very significant improvement in the detection was seen with the E. coli cell lysate (5 × 104 CFU/ml). Finally we developed Electrochemical Impedance Spectroscopy (EIS) gap capacitance biosensor that has detection limits of 2 × 104 CFU/mL of E. coli cells, without any labeling and signal amplification techniques. We believe that our developed method can step towards more complex and real sample application.

ALPPL2 Aptamer-Mediated Targeted Delivery of 5-Fluoro-2'-Deoxyuridine to Pancreatic Cancer.

Nucleoside analogues are the most promising drugs for the treatment of pancreatic cancer to date. However, their use is often limited due to toxic side effects. Aptamer-mediated targeted delivery of these drugs to cancer cells could maximize their effectiveness and concomitantly minimize the toxic side effects by reducing uptake into normal cells. Previously, we identified a pancreatic cancer-specific, nuclease-resistant RNA aptamer, SQ2, which binds to alkaline phosphatase placental-like 2 (ALPPL2), a putative biomarker for pancreatic cancer. In this study, we demonstrate that the aptamer can be internalized into pancreatic cancer cells and can thus be used for the targeted delivery of therapeutics. Using the aptamer as a ligand, we established that glycophosphatidylinositol-anchored ALPPL2 is internalized by the cells through clathrin-independent and caveolae-dependent or dynamin-mediated cell-type-dependent pathways. Finally, we show that SQ2 can deliver nucleoside drug 5-fluoro-2'-deoxyuridine specifically to ALPPL2-expressing pancreatic cancer cells, inhibiting cell proliferation.

Long dsRNA-mediated RNA interference and immunostimulation: a targeted delivery approach using polyethyleneimine based nano-carriers.

RNA oligonucleotides capable of inducing controlled immunostimulation combined with specific oncogene silencing via an RNA interference (RNAi) mechanism provide synergistic inhibition of cancer cell growth. With this concept, we previously designed a potent immunostimulatory long double stranded RNA, referred to as liRNA, capable of executing RNAi mediated specific target gene silencing. In this study, we developed a highly effective liRNA based targeted delivery system to apply in the treatment of glioblastoma multiforme. A stable nanocomplex was fabricated by complexing multimerized liRNA structures with cross-linked branched poly(ethylene imine) (bPEI) via electrostatic interactions. We show clear evidence that the cross-linked bPEI was quite effective in enhancing the cellular uptake of liRNA on U87MG cells. Moreover, the liRNA-PEI nanocomplex provided strong RNAi mediated target gene silencing compared to that of the conventional siRNA-PEI complex. Further, the bPEI modification strategy with specific ligand attachment assisted the uptake of the liRNA-PEI complex on the mouse brain endothelial cell line (b.End3). Such delivery systems combining the beneficial elements of targeted delivery, controlled immunostimulation, and RNAi mediated target silencing have immense potential in anticancer therapy.

Alkaline phosphatase ALPPL-2 is a novel pancreatic carcinoma-associated protein.

Pancreatic ductal adenocarcinoma (PDAC) is a highly aggressive malignancy with a very low median survival rate. The lack of early sensitive diagnostic markers is one of the main causes of PDAC-associated lethality. Therefore, to identify novel pancreatic cancer biomarkers that can facilitate early diagnosis and also help in the development of effective therapeutics, we developed RNA aptamers targeting pancreatic cancer by Cell-systematic evolution of ligands by exponential enrichment (SELEX) approach. Using a selection strategy that could generate aptamers for 2 pancreatic cancer cell lines in one selection scheme, we identified an aptamer SQ-2 that could recognize pancreatic cancer cells with high specificity. Next, by applying 2 alternative approaches: (i) aptamer-based target pull-down and (ii) genome-wide microarray-based identification of differentially expressed mRNAs in aptamer-positive and -negative cells, we identified alkaline phosphatase placental-like 2 (ALPPL-2), an oncofetal protein, as the target of SQ-2. ALPPL-2 was found to be ectopically expressed in many pancreatic cancer cell lines at both mRNA and protein levels. RNA interference-mediated ALPPL-2 knockdown identified novel tumor-associated functions of this protein in pancreatic cancer cell growth and invasion. In addition, the aptamer-mediated identification of ALPPL-2 on the cell surface and cell secretions of pancreatic cancer cells supports its potential use in the serum- and membrane-based diagnosis of PDAC.

The design, preparation, and evaluation of asymmetric small interfering RNA for specific gene silencing in mammalian cells.

RNA interference (RNAi) is a highly efficient endogenous gene silencing mechanism mediated by short double-stranded RNAs termed small interfering RNAs (siRNAs). The current standard siRNA structure, which is used by most researchers to trigger sequence-specific target gene silencing, consists of a double strand region of 19 bp with 2 nt 3'-overhangs at both ends. However, in addition to the desired target gene silencing, this conventional siRNA structure also exhibits several unintended effects that constitute obstacles to the use of siRNA in gene function studies and therapeutics development. Here, we provide protocols for designing and preparing an alternative structure for RNAi trigger, termed asymmetric shorter-duplex RNA (asiRNA). The asiRNA structure has a duplex region shorter than 19 bp and has an asymmetric 3'-overhang structure. Importantly, the asiRNA structure not only triggers efficient target gene silencing comparable to that of the 19 bp standard siRNA structure but also significantly reduces nonspecific effects triggered by 19 bp siRNAs such as sense-strand-mediated off-target silencing and the saturation of RNAi machinery. Procedures are described for verifying that asiRNA activates gene silencing through an Ago2-dependent pathway and for assessing the miRNA pathway competition potency and specific and nonspecific silencing abilities of asiRNAs. We propose that asiRNA, an improved RNAi trigger that can overcome the nonspecific effects evoked by standard siRNA structures, can be developed as a precise and effective tool for both functional genomics and therapeutic applications.

Dual functions of highly potent graphene derivative-poly-L-lysine composites to inhibit bacteria and support human cells.

Dual-function poly(L-lysine) (PLL) composites that function as antibacterial agents and promote the growth of human cell culture have been sought by researchers for a long period. In this paper, we report the preparation of new graphene derivative-PLL composites via electrostatic interactions and covalent bonding between graphene derivatives and PLL. The resulting composites were characterized by infrared spectroscopy, scanning electron microscopy, and X-ray photoelectron spectroscopy. The novel dual function of PLL composites, specifically antibacterial activity and biocompatibility with human cells [human adipose-derived stem cells and non-small-cell lung carcinoma cells (A549)], was carefully investigated. Graphene-DS-PLL composites composed of 4-carboxylic acid benzene diazonium salt (DS) generated more anionic carboxylic acid groups to bind to cationic PLLs, forming the most potent antibacterial agent among PLL and PLL composites with high biocompatibility with human cell culture. This dual functionality can be used to inhibit bacterial growth while enhancing human cell growth.

Enhanced intracellular delivery and multi-target gene silencing triggered by tripodal RNA structures.

BACKGROUND: The development of gene interfering RNA (iRNA) molecules such as small interfering RNAs (siRNAs) and antagomirs provides promising therapeutic modalities for targeting specific mRNAs and microRNAs (miRNAs) involved in disease mechanisms. Therapeutic iRNA strategy against cancer or hypermutable viruses prefers targeting multiple genes simultaneously to achieve synergistic inhibition and to prevent resistance. METHODS: In the present study, we report chemically synthesized, multi-target gene interfering RNA structures based upon branched, tripodal interfering RNAs (termed T-tiRNAs). RESULTS: The T-tiRNAs could simultaneously inhibit up to three different mRNAs or miRNAs by harboring three siRNA or antagomir units. Moreover, when complexed with cationic delivery vehicles, T-tiRNAs showed enhanced gene interfering activity over conventional siRNAs or antagomirs as a result of increased intracellular delivery. CONCLUSIONS: The data obtained in the present study provide an example of synthetic multi-functional RNA structures that enable multiple gene interference in mammalian cells, which could become powerful tools for an efficient combinatorial iRNA strategy.

Structural diversity repertoire of gene silencing small interfering RNAs.

Since the discovery of double-stranded (ds) RNA-mediated RNA interference (RNAi) phenomenon in Caenorhabditis elegans, specific gene silencing based upon RNAi mechanism has become a novel biomedical tool that has extended our understanding of cell biology and opened the door to an innovative class of therapeutic agents. To silence genes in mammalian cells, short dsRNA referred to as small interfering RNA (siRNA) is used as an RNAi trigger to avoid nonspecific interferon responses induced by long dsRNAs. An early structure-activity relationship study performed in Drosophila melanogaster embryonic extract suggested the existence of strict siRNA structural design rules to achieve optimal gene silencing. These rules include the presence of a 3' overhang, a fixed duplex length, and structural symmetry, which defined the structure of a classical siRNA. However, several recent studies performed in mammalian cells have hinted that the gene silencing siRNA structure could be much more flexible than that originally proposed. Moreover, many of the nonclassical siRNA structural variants reported improved features over the classical siRNAs, including increased potency, reduced nonspecific responses, and enhanced cellular delivery. In this review, we summarize the recent progress in the development of gene silencing siRNA structural variants and discuss these in light of the flexibility of the RNAi machinery in mammalian cells.

Long double-stranded RNA-mediated RNA interference and immunostimulation: long interfering double-stranded RNA as a potent anticancer therapeutics.

In most applications, small interfering RNAs are designed to execute specific gene silencing via RNA interference (RNAi) without triggering nonspecific responses such as immunostimulation. However, in anticancer therapeutics, immunostimulation combined with specific oncogene silencing could be beneficial, resulting in the synergistic inhibition of cancer cell growth. In this study, we report an immunostimulatory long double-stranded RNA (dsRNA) structure with the ability to trigger RNAi-mediated specific target gene silencing, termed as long interfering dsRNA (liRNA). liRNA targeting Survivin mRNA not only efficiently and specifically triggered target gene silencing via RNAi, but also stimulated the protein kinase R pathway to induce the expression of interferon ß. As a result, the ability of Survivin-targeting liRNA to inhibit cancer cell growth was superior over conventional small interfering RNA or nontargeting dsRNA structures. Our results thus provide a simple yet efficient dual function immunostimulatory RNAi-triggering structure, which is potentially applicable for the development of anticancer therapeutics.

Modified siRNA structure with a single nucleotide bulge overcomes conventional siRNA-mediated off-target silencing.

Off-target gene silencing is a major concern when using RNA interference. Imperfect pairing of the antisense strand with unintended mRNA targets is one of the main causes of small interfering RNA (siRNA) off-target silencing. To overcome this, we have developed "bulge-siRNA," a modified siRNA backbone structure with a single nucleotide (nt) bulge placed in the antisense strand. We found that siRNAs with a bulge at position 2 of the antisense strand were able to discriminate better between perfectly matched and mismatched targets, with no loss in silencing of the intended target. Genome-wide analysis also revealed that the bulge-siRNAs significantly reduced off-target silencing of transcripts with complementarity to the seed region of the siRNA antisense strand. When compared to 2'-methoxy ribosyl (2'-OMe) modified siRNAs previously developed to alleviate antisense off-target silencing; the bulge modification could better discriminate between on- versus off-targets. Our results suggest that the bulge-siRNA structure is a simple, yet superior alternative to chemical modifications for minimizing off-target silencing triggered by conventional siRNA structures.

Development of single-stranded DNA aptamers for specific Bisphenol a detection.

The development of reagents with high affinity and specificity to small molecules is crucial for the high-throughput detection of chemical compounds, such as toxicants or pollutants. Aptamers are short and single-stranded (ss) oligonucleotides able to recognize target molecules with high affinity. Here, we report the selection of ssDNA aptamers that bind to Bisphenol A (BPA), an environmental hormone. Using SELEX process, we isolated high affinity aptamers to BPA from a 10(15) random library of 60 mer ssDNAs. The selected aptamers bound specifically to BPA, but not to structurally similar molecules, such as Bisphenol B with one methyl group difference, or 4,4'-Bisphenol with 2 methyl groups difference. Using these aptamers, we developed an aptamer-based sol-gel biochip and detected BPA dissolved in water. This novel BPA aptamer-based detection can be further applied to the universal and high-specificity detection of small molecules.

A sol-gel-based microfluidics system enhances the efficiency of RNA aptamer selection.

RNA and DNA aptamers that bind to target molecules with high specificity and affinity have been a focus of diagnostics and therapeutic research. These aptamers are obtained by SELEX often requiring many rounds of selection and amplification. Recently, we have shown the efficient binding and elution of RNA aptamers against target proteins using a microfluidic chip that incorporates 5 sol-gel binding droplets within which specific target proteins are imbedded. Here, we demonstrate that our microfluidic chip in a SELEX experiment greatly improved selection efficiency of RNA aptamers to TATA-binding protein, reducing the number of selection cycles needed to produce high affinity aptamers by about 80%. Many aptamers were identical or homologous to those isolated previously by conventional filter-binding SELEX. The microfluidic chip SELEX is readily scalable using a sol-gel microarray-based target multiplexing. Additionally, we show that sol-gel embedded protein arrays can be used as a high-throughput assay for quantifying binding affinities of aptamers.

Nucleic acid aptamers targeting cell-surface proteins.

Aptamers are chemical antibodies that bind to their targets with high affinity and specificity. These short stretches of nucleic acids are identified using a repetitive in vitro selection and partitioning technology called SELEX (Systematic Evolution of Ligands by EXponential enrichment). Since the emergence of this technology, many modifications and variations have been introduced to enable the selection of specific ligands, even for implausible targets. For membrane protein, the selection scheme can be chosen depending upon the availability of the system, the protein characteristics and the application required. Aptamers have been generated for a significant number of disease-associated membrane proteins and have been shown to have considerable diagnostic and therapeutic importance. In this article, we review the SELEX process used for identification of aptamers that target cell-surface proteins and recapitulate their use as therapeutic and diagnostic reagents.

Patents on SELEX and therapeutic aptamers.

Aptamers, the oligonucleotides (DNA/RNA) that bind to target molecules with high specificity and affinity, have been a focus of therapeutic research for the last two decades. The magnitude of scientific and commercial interest shown for aptamers is not surprising because aptamers have several advantages over other curative modalities, especially antibodies. Patent activity in this field has also shown an exponential growth. Aptamers against a broad range of disease-causing pathogens and proteins have been patented. These have potential use as a biomarker, therapeutics and diagnostics. As drugs they have shown commendable results in cell and animal models, a few of them undergoing clinical trials. In this review, we discuss upon all important patents filed on therapeutic aptamers and SELEX technology employed to synthesize them. We have classified them in categories based upon their target or the diseased condition they apt for. These patents provide insight into the development that occurred in transformation of aptamers as therapeutic entities and reinforces the potential they have.

Pentoxifylline impedes migration in B16F10 melanoma by modulating Rho GTPase activity and actin organisation.

Cancer cell migration is a hallmark of metastatic cascade and compounds that can intervene in this process are clinically important. Pentoxifylline (PTX), a methyl xanthine derivative, inhibits B16F10 melanoma lung homing by inhibiting F10 invasion, MMP secretion and adhesion to matrix components. However, its effect on B16F10 migration remained unexamined, which we investigated in the present study. PTX significantly inhibits F10 migration in scratch wound assay. Elevation in cAMP levels inhibits F10 migration and PTX mediated inhibition of the process was found to be, in part, due to an increase in cellular cAMP levels. PTX induces Protein Kinase A (PKA) activity and PKA inhibitor partly reversed its effects on F10 motility. RhoA and Rac1 GTPases induce B16F10 motility and PTX was found to inhibit migration by affecting these molecules. Stress fibres and lamellipodial protrusions reduced significantly. This was accompanied with inhibition in RhoA and Rac1 membrane localisation. A stark inhibition in RhoA-GTP bound form was also observed. Taken together, the results indicate that PTX, through its phosphodiesterase action, inhibits RhoGTPases and associated actin organisation in B16F10 melanoma, thereby inhibiting cell motility.