U1 Adaptors Suppress the KRAS-MYC Oncogenic Axis in Human Pancreatic Cancer Xenografts.

Targeting KRAS and MYC has been a tremendous challenge in cancer drug development. Genetic studies in mouse models have validated the efficacy of silencing expression of both KRAS and MYC in mutant KRAS-driven tumors. We investigated the therapeutic potential of a new oligonucleotide-mediated gene silencing technology (U1 Adaptor) targeting KRAS and MYC in pancreatic cancer. Nanoparticles in complex with anti-KRAS U1 Adaptors (U1-KRAS) showed remarkable inhibition of KRAS in different human pancreatic cancer cell lines in vitro and in vivo As a nanoparticle-free approach is far easier to develop into a drug, we refined the formulation of U1 Adaptors by conjugating them to tumor-targeting peptides (iRGD and cRGD). Peptides coupled to fluorescently tagged U1 Adaptors showed selective tumor localization in vivo Efficacy experiments in pancreatic cancer xenograft models showed highly potent (>90%) antitumor activity of both iRGD and (cRGD)2-KRAS Adaptors. U1 Adaptors targeting MYC inhibited pancreatic cancer cell proliferation caused by apoptosis in vitro (40%-70%) and tumor regressions in vivo Comparison of iRGD-conjugated U1 KRAS and U1 MYC Adaptors in vivo revealed a significantly greater degree of cleaved caspase-3 staining and decreased Ki67 staining as compared with controls. There was no significant difference in efficacy between the U1 KRAS and U1 MYC Adaptor groups. Our results validate the value in targeting both KRAS and MYC in pancreatic cancer therapeutics and provide evidence that the U1 Adaptor technology can be successfully translated using a nanoparticle-free delivery system to target two undruggable genes in cancer. Mol Cancer Ther; 16(8); 1445-55. ©2017 AACR.

U1 Adaptor Oligonucleotides Targeting BCL2 and GRM1 Suppress Growth of Human Melanoma Xenografts In Vivo.

U1 Adaptor is a recently discovered oligonucleotide-based gene-silencing technology with a unique mechanism of action that targets nuclear pre-mRNA processing. U1 Adaptors have two distinct functional domains, both of which must be present on the same oligonucleotide to exert their gene-silencing function. Here, we present the first in vivo use of U1 Adaptors by targeting two different human genes implicated in melanomagenesis, B-cell lymphoma 2 (BCL2) and metabotropic glutamate receptor 1 (GRM1), in a human melanoma cell xenograft mouse model system. Using a newly developed dendrimer delivery system, anti-BCL2 U1 Adaptors were very potent and suppressed tumor growth at doses as low as 34 µg/kg with twice weekly intravenous (iv) administration. Anti-GRM1 U1 Adaptors suppressed tumor xenograft growth with similar potency. Mechanism of action was demonstrated by showing target gene suppression in tumors and by observing that negative control U1 Adaptors with just one functional domain show no tumor suppression activity. The anti-BCL2 and anti-GRM1 treatments were equally effective against cell lines harboring either wild-type or a mutant V600E B-RAF allele, the most common mutation in melanoma. Treatment of normal immune-competent mice (C57BL6) indicated no organ toxicity or immune stimulation. These proof-of-concept studies represent an in-depth (over 800 mice in ~108 treatment groups) validation that U1 Adaptors are a highly potent gene-silencing therapeutic and open the way for their further development to treat other human diseases.Molecular Therapy - Nucleic Acids (2013) 2, e92; doi:10.1038/mtna.2013.24; published online 14 May 2013.

Ectopic 5' splice sites inhibit gene expression by engaging RNA surveillance and silencing pathways in plants.

The quality control of mRNA maturation is a highly regulated process that surveys pre-mRNA integrity and eliminates improperly matured pre-mRNAs. In nature, certain viruses regulate the expression of their genes by hijacking the endogenous RNA quality control machinery. We demonstrate that the inclusion of 5' splice sites within the 3'-untranslated region of a reporter gene in plants alters the pre-mRNA cleavage and polyadenylation process, resulting in pre-mRNA degradation, exemplifying a regulatory mechanism conserved between kingdoms. Altered pre-mRNA processing was associated with an inhibition of homologous gene expression in trans and the preferential accumulation of 24-nucleotide (nt) short-interfering RNAs (siRNAs) as opposed to 21-nt siRNA subspecies, suggesting that degradation of the aberrant pre-mRNA involves the silencing machinery. However, gene expression was not restored by coexpression of a silencing suppressor or in an RNA-dependent RNA polymerase (RDR6)-deficient background despite reduced 24-nt siRNA accumulation. Our data highlight a complex cross talk between the quality control RNA machinery, 3'-end pre-mRNA maturation, and RNA-silencing pathways capable of discriminating among different types of aberrant RNAs.

Gene silencing by synthetic U1 adaptors.

We describe a gene silencing method that employs a mechanism of action distinct from those of antisense and RNA interference. U1 Adaptors are bifunctional oligonucleotides with a 'target domain' complementary to a site in the target gene's terminal exon and a 'U1 domain' that binds to the U1 small nuclear RNA component of the U1 small nuclear ribonucleoprotein (U1 snRNP) splicing factor. Tethering of U1 snRNP to the target pre-mRNA inhibits poly(A)-tail addition, causing degradation of that RNA species in the nucleus. U1 Adaptors can inhibit both endogenous and reporter genes in a sequence-specific manner. Comparison of U1 Adaptors with small interfering RNA (siRNA) using a genome-wide microarray analysis indicates that U1 Adaptors have limited off-target effects and no detectable adverse effects on splicing. Further, targeting the same gene either with multiple U1 Adaptors or with a U1 Adaptor and siRNA strongly enhances gene silencing.

The regulatory element in the 3'-untranslated region of human papillomavirus 16 inhibits expression by binding CUG-binding protein 1.

The 3'-untranslated regions (UTRs) of human papillomavirus 16 (HPV16) and bovine papillomavirus 1 (BPV1) contain a negative regulatory element (NRE) that inhibits viral late gene expression. The BPV1 NRE consists of a single 9-nucleotide (nt) U1 small nuclear ribonucleoprotein (snRNP) base pairing site (herein called a U1 binding site) that via U1 snRNP binding leads to inhibition of the late poly(A) site. The 79-nt HPV16 NRE is far more complicated, consisting of 4 overlapping very weak U1 binding sites followed by a poorly understood GU-rich element (GRE). We undertook a molecular dissection of the HPV16 GRE and identify via UV cross-linking, RNA affinity chromatography, and mass spectrometry that is bound by the CUG-binding protein 1 (CUGBP1). Reporter assays coupled with knocking down CUGBP1 levels by small interfering RNA and Dox-regulated shRNA, demonstrate CUGBP1 is inhibitory in vivo. CUGBP1 is the first GRE-binding protein to have RNA interfering knockdown evidence in support of its role in vivo. Several fine-scale GRE mutations that inactivate GRE activity in vivo and GRE binding to CUGBP1 in vitro are identified. The CUGBP1.GRE complex has no activity on its own but specifically synergizes with weak U1 binding sites to inhibit expression in vivo. No synergy is seen if the U1 binding sites are made weaker by a 1-nt down-mutation or made stronger by a 1-nt up-mutation, underscoring that the GRE operates only on weak sites. Interestingly, inhibition occurs at multiple levels, in particular at the level of poly(A) site activity, nuclear-cytoplasmic export, and translation of the mRNA. Implications for understanding the HPV16 life cycle are discussed.

A bipartite U1 site represses U1A expression by synergizing with PIE to inhibit nuclear polyadenylation.

U1A protein negatively autoregulates itself by polyadenylation inhibition of its own pre-mRNA by binding as two molecules to a 3'UTR-located Polyadenylation Inhibitory Element (PIE). The (U1A)2-PIE complex specifically blocks U1A mRNA biosynthesis by inhibiting polyA tail addition, leading to lower mRNA levels. U1 snRNP bound to a 5'ss-like sequence, which we call a U1 site, in the 3'UTRs of certain papillomaviruses leads to inhibition of viral late gene expression via a similar mechanism. Although such U1 sites can also be artificially used to potently silence reporter and endogenous genes, no naturally occurring U1 sites have been found in eukaryotic genes. Here we identify a conserved U1 site in the human U1A gene that is, unexpectedly, within a bipartite element where the other part represses the U1 site via a base-pairing mechanism. The bipartite element inhibits U1A expression via a synergistic action with the nearby PIE. Unexpectedly, synergy is not based on stabilizing binding of the inhibitory factors to the 3'UTR, but rather is a property of the larger ternary complex. Inhibition targets the biosynthetic step of polyA tail addition rather than altering mRNA stability. This is the first example of a functional U1 site in a cellular gene and of a single gene containing two dissimilar elements that inhibit nuclear polyadenylation. Parallels with other examples where U1 snRNP inhibits expression are discussed. We expect that other cellular genes will harbor functional U1 sites.