Antibody targeted siRNA delivery.

It is very clear that RNA interference (RNAi) is a potent and versatile tool for gene silencing. One of the hurdles to making siRNA/miRNA a human therapeutic includes effective in vivo delivery and being able to deliver drugs to target cells only. The commercial success of in vivo applications of RNAi hinges on the development of new delivery methods. Our strategy involves the use of antibody-based delivery agents to target and deliver siRNA into specific cell types. We have developed antibody-based agents for directed delivery into cultured cells and animal disease models. Using antibodies against various cell surface receptors, modified siRNAs are attached to antibody complexes using RNA carrier proteins. The complex can then be intravenously administered to in vivo models and taken up by specific cells via receptor-mediated endocytosis. The labile structure of the linking agents enables release of siRNA molecules post internalization. Using this targeting strategy, we have developed a method that allows any commercially available or recombinant antibody to be conjugated to siRNA for delivery purposes.

Delivery of RNAi mediators.

Delivering polynucleotides into animals has been a major challenge facing their success as therapeutic agents. Given the matured understanding of antibody-mediated delivery techniques, it is possible to rationally design delivery vehicles that circulate in the blood stream and are specifically delivered into target organs. If the targeting moiety is designed to contain the cargo of an RNAi mediator without impacting its paratope, directed delivery can be achieved. In this article, we review the state of art in delivery technology for RNA mediators and address how this technique could soon be used to enhance the efficacy of the numerous small RNA therapeutic programs currently under evaluation.

Using synthetic precursor and inhibitor miRNAs to understand miRNA function.

Although the majority of gene function studies center themselves around protein-encoding RNAs, the study of non-protein-encoding RNAs is becoming more widespread because of the discovery of hundreds of small RNA termed micro (mi) RNA that have regulator functions within cells. Currently, over 470 human miRNA genes are predicted to exist and are annotated within the "miRBase" public miRNA database ( http://microrna.sanger.ac.uk/ ). There is no denying that short interfering (si) and short hairpin (sh) RNAs have revolutionized how scientists approach understanding gene function; however, si and shRNAs are not effective for analyzing the function of miRNAs given that miRNAs are typically short (17-24 bases). In turn, new sets of agents that allow for the expression of miRNA above endogenous levels and inhibition of miRNAs have become a valuable technology for the study of these small regulatory RNAs. In this chapter, we provide step-by-step methods on how to utilize synthetic precursor and antisense inhibitor molecules for understanding miRNA function.

A step-by-step procedure to analyze the efficacy of siRNA using real-time PCR.

Knockdown of cellular RNA using short interfering RNA has enabled researchers to perform loss-of-function (LOF) experiments in a wide variety of cell types and model systems. RNA interference techniques and reagents have made possible experiments that test everything from the analysis of function of single genes to screening for genes that are involved in critical biological pathways on a genome-wide scale. Although siRNA experiments are generally common practice in research laboratories, it is still important to keep in mind that many factors can influence efficacy of knockdown. A properly designed siRNA, optimized protocols of siRNA delivery, and an appropriate and well-optimized readout are all critical parameters for ensuring the success of your experiment. In this chapter, we provide step-by-step procedures for performing an siRNA knockdown experiment from cell culture to analysis of knockdown using quantitative real-time PCR.

Applying small RNA molecules to the directed treatment of human diseases: realizing the potential.

Small interfering RNAs (siRNA) and microRNAs (miRNA) are gaining considerable attention in the pharmaceutical and biotechnology industries, as research has revealed their likely clinical and agricultural applications. The capacity of siRNAs to dramatically and specifically reduce the expression of targeted genes has spawned multiple clinical trials to establish the therapeutic potential of small RNAs targeting viral, cancer and other disease-related genes. The successful application of siRNAs will enable the development of therapeutic applications based on miRNAs that have been observed to contribute to a variety of human diseases. This article reviews advances that have been made to apply small RNAs as therapeutics.

Role of miRNA and miRNA processing factors in development and disease.

Mature microRNAs (miRNAs) are single-stranded RNA molecules of 17-24 nucleotides (nt) in length that are encoded in the genomes of plants and animals. The seminal discoveries of miRNA made in C. elegans have led the way to the rampant discoveries being made today in this field. Since each miRNA is predicted and in some cases confirmed to regulate multiple genes, the potential regulatory circuitry afforded by miRNAs is thought to be enormous and could amount to regulation of >30% of all human genes. Due to the sequences of many of the miRNAs being highly homologous among organisms, the huge potential of miRNAs to regulate gene expression, and the hints of miRNAs being useful in both diagnostics and therapeutics, it is no wonder these small RNAs are gaining such popularity in both the academic and industrial settings. It is now becoming clear that the miRNA gene class represents a very important gene regulatory network. This article reviews the initial discoveries of miRNA that began in the nematode C. elegans, and extends into what is known about miRNAs and miRNA processing factors in mouse development and human disease.

Ku protein targeting by Ku70 small interfering RNA enhances human cancer cell response to topoisomerase II inhibitor and gamma radiation.

Ku protein is a heterodimer (Ku70 and Ku86) known to play an important role in V(D)J recombination, apoptosis, telomere fusion, and double-strand break repair. Its role in double-strand breaks is relevant to cancer therapy because lack of Ku86 causes one of the most radiation-responsive phenotypes (hamster cells, XRS5). Although it is known that the heterodimer is necessary for the various functions of this protein, the impact of targeting Ku in human cancer cells has not been shown due to lack of appropriate approaches. It is also not known whether complete knock-out of Ku protein is required to enhance the sensitivity of human cells to gamma radiation as Ku protein is much more abundant in human cells than in hamster cells. In the current article, we have investigated the direct effect of Ku70 depletion in human cervical epithelioid (HeLa) and colon carcinoma (HCT116) cells. We specifically targeted Ku70 mRNA by use of small interfering RNA (siRNA). Of the five Ku70 siRNA synthesized, three inhibited the expression of Ku70 by up to 70% in HeLa cells. We have tested the effect of chemically synthesized siRNAs for target sequence 5 (CS #5) on the response of HeLa cells 72 hours after transfection to gamma radiation and etoposide, as this showed the maximum inhibition of Ku70 expression. Ku70 siRNA induced a decrease in the surviving fraction of irradiated HeLa cells by severalfold. Similar sensitizing effects were observed for etoposide, a topoisomerase II inhibitor. Studies with HCT116 cells using the same Ku70 siRNA (CS #5) showed a direct correlation between expression of Ku70 and sensitization to radiation and etoposide treatments.

Antisense inhibition of human miRNAs and indications for an involvement of miRNA in cell growth and apoptosis.

Of the over 200 identified mammalian microRNAs (miRNAs), only a few have known biological activity. To gain a better understanding of the role that miRNAs play in specific cellular pathways, we utilized antisense molecules to inhibit miRNA activity. We used miRNA inhibitors targeting miR-23, 21, 15a, 16 and 19a to test efficacy of antisense molecules in reducing miRNA activity on reporter genes bearing miRNA-binding sites. The miRNA inhibitors de-repressed reporter gene activity when a miRNA-binding site was cloned into its 3'-untranslated region. We employed a library of miRNA inhibitors to screen for miRNA involved in cell growth and apoptosis. In HeLa cells, we found that inhibition of miR-95, 124, 125, 133, 134, 144, 150, 152, 187, 190, 191, 192, 193, 204, 211, 218, 220, 296 and 299 caused a decrease in cell growth and that inhibition of miR-21 and miR-24 had a profound increase in cell growth. On the other hand, inhibition of miR-7, 19a, 23, 24, 134, 140, 150, 192 and 193 down-regulated cell growth, and miR-107, 132, 155, 181, 191, 194, 203, 215 and 301 increased cell growth in lung carcinoma cells, A549. We also identified miRNA that when inhibited increased the level of apoptosis (miR-1d, 7, 148, 204, 210, 216 and 296) and one miRNA that decreased apoptosis (miR-214) in HeLa cells. From these screens, we conclude that miRNA-mediated regulation has a complexity of cellular outcomes and that miRNAs can be mediators of regulation of cell growth and apoptosis pathways.

BCR/ABL activates mdm2 mRNA translation via the La antigen.

In a BCR/ABL-expressing myeloid precursor cell line, p53 levels were markedly downmodulated. Expression of MDM2, the negative regulator of p53, was upregulated in a tyrosine kinase-dependent manner in growth factor-independent BCR/ABL-expressing cells, and in accelerated phase and blast crisis CML samples. Increased MDM2 expression was associated with enhanced mdm2 mRNA translation, which required the interaction of the La antigen with mdm2 5' UTR. Expression of MDM2 correlated with that of La and was suppressed by La siRNAs and by a dominant negative La mutant, which also enhanced the susceptibility to drug-induced apoptosis of BCR/ABL-transformed cells. By contrast, La overexpression led to increased MDM2 levels and enhanced resistance to apoptosis. Thus, La-dependent activation of mdm2 translation might represent an important molecular mechanism involved in BCR/ABL leukemogenesis.

Human Ku70/80 associates physically with telomerase through interaction with hTERT.

Telomere length maintenance, an activity essential for chromosome stability and genome integrity, is regulated by telomerase- and telomere-associated factors. The DNA repair protein Ku (a heterodimer of Ku70 and Ku80 subunits) associates with mammalian telomeres and contributes to telomere maintenance. Here, we analyzed the physical association of Ku with human telomerase both in vivo and in vitro. Antibodies specific to human Ku proteins precipitated human telomerase in extracts from tumor cells, as well as from telomerase-immortalized normal cells, regardless of the presence of DNA-dependent protein kinase catalytic subunit. The same Ku antibodies also precipitated in vitro reconstituted telomerase, suggesting that this association does not require telomeric DNA. Moreover, Ku associated with the in vitro translated catalytic subunit of telomerase (hTERT) in the absence of telomerase RNA (hTR) or telomeric DNA. The results presented here are the first to report that Ku associates with hTERT, and this interaction may function to regulate the access of telomerase to telomeric DNA ends.

c-Myc controls proliferation versus differentiation in human pancreatic endocrine cells.

Using immortalized human pancreatic endocrine cell lines, we have shown previously that differentiation into hormone-expressing cells requires cell-cell contact acting in synergy with the homeodomain transcription factor pancreatic duodenal homeobox-1 (PDX-1). Although differentiation is associated with a decrease in cell proliferation, the mechanisms behind this relationship are not known. Using TRM-6, a delta cell line, and betalox5, a beta-cell line, we show here that cell-cell contact and subsequent endocrine differentiation lead to a down-regulation of the c-myc protooncogene. Overexpression of c-Myc obtained with an inducible c-Myc-estrogen receptor fusion protein results in an increase in cell proliferation and the ablation of hormone expression. Moreover, we show that although c-Myc is expressed in a subset of cells from the human fetal and adult pancreas, it is absent in differentiated endocrine cells. The mechanism by which c-Myc interferes with hormone expression may be through effects on the homeodomain transcription factor PDX-1, as immunostaining for PDX-1 in cells with activated c-Myc revealed a redistribution of PDX-1 from the nucleus to the cytoplasm. These results suggest that c-Myc plays a central role in a cell-cell contact-mediated switch mechanism by which cell division vs. differentiation in endocrine cells is determined.

A model for heterogeneous nuclear ribonucleoproteins in telomere and telomerase regulation.

The heterogeneous nuclear ribonucleoproteins (hnRNPs) are a large family of nucleic acid binding proteins that are often found in, but not restricted to, the 40S-ribonucleoprotein particle. Subsets of hnRNPs are strictly nuclear while others shuttle between the nucleus and cytoplasm. Members of the hnRNP family have been implicated to have roles in many aspects of mRNA maturation/turnover and in telomere and telomerase regulation. Telomeres are repetitive DNA elements mainly found at the ends of human chromosomes. In most normal cells, telomeres shorten with each cell division. Telomere shortening can be compensated for by a ribonucleoprotein complex, called telomerase. Telomerase, consisting of an integral RNA and catalytic protein component as well as several auxiliary factors, extends the 3'-G-rich strand of the ends of the telomeres. Here we present new data and describe a model that implicates the telomerase bound hnRNPs in promoting telomere access by interacting with telomeres. Telomere bound hnRNPs include hnRNP A1, A2-B1, D and E and telomerase bound hnRNPs including hnRNPA1 C1/C2 and D. The telomere and telomerase bound hnRNPs may prove to be good targets for regulating telomere length.