Broad-spectrum metastasis suppressing compounds and therapeutic uses thereof in human tumors.

Previously, we have identified a novel human metastasis-inducing lncRNA (named SKAI1BC), that suppresses the KAI1/CD82 metastasis-suppressing gene and is upregulated in triple negative breast cancer and melanoma derived cell lines. Modeling of the SKAI1BC lncRNA secondary structure and its potential interaction with Inforna compounds, led us to identify several compounds that might bind the SKAI1BC lncRNA. We found that these compounds inhibit metastasis invasion and cell migration in culture, in all eight types of solid human cancers tested: several of which are the most lethal and/or frequent human malignancies. Moreover, in most cases, the mechanism of action of several of our compounds involves enhancement of KAI1/CD82 RNA level depending on the specific compound and the human tumor type. With the epigenetic inactivation of KAI1/CD82 in at least ten additional solid human cancers, this implies a very good chance to broaden the spectrum of human cancers affected by our compounds. This is the first time that modeling of a large lncRNA (> 700 bp) secondary structure followed by its potential interaction with Inforna like compounds database has led to the identification of potential biologically active small molecule drugs.

Visualizing nuclear RNAi activity in single living human cells.

Nuclear RNA interference (RNAi) is mediated by the canonical RNAi machinery and can lead to transcriptional silencing, transcriptional activation, or modulation of alternative splicing patterns. These effects transpire through changes in histone and DNA modifications via RNAi-mediated recruitment of chromatin-modifying enzymes. To prove that nuclear RNAi occurs and modulates transcription in human cells, we used live-cell imaging to detect and track nuclear RNAi transcriptional repression in single living human cells. While employing reporter genes constructed with inducible promoters and cognate-inducible short hairpin RNA (shRNA) targeted against the reporter coding region, we have characterized the dynamics of the nuclear RNAi process in living human cells. We show that the silencing effect is mediated through the nascent mRNA, followed by activity of histone methylating enzymes, but not through DNA methylation.

Identification of a novel metastasis inducing lncRNA which suppresses the KAI1/CD82 metastasis suppressor gene and is upregulated in triple-negative breast cancer.

Inactivation of tumor/metastasis suppressor genes via epigenetic silencing is a frequent event in human cancers. KAI1/CD82 is a metastasis suppressor gene whose normal protecting activity is deficient in twelve different solid malignancies. Here we have identified and characterized a primarily nuclear non-polyadenylated, antisense (as)-lncRNA, initiating upstream of the KAI1 human metastasis suppressor gene transcription start site; and elongating in the opposite direction to KAI1 mRNA. We show that the KAI1 promoter is bi-directional giving rise to KAI1 mRNA and its as-lncRNA. Moreover, expression of this lncRNA transcript emerges to be inversely related to the KAI1 mRNA expression, and in direct relationship to the invasiveness level of human breast cancer derived cell lines. Importantly, knockdown of the KAI1 as-lncRNA in the triple-negative breast cancer cell line MDA-MB-231 have led to increased KAI1 mRNA and protein expression, manifested in stronger adhesion to fibronectin, retardation of cell migration and reduced cell invasion in vitro. Accordingly we have named this lncRNA, SKAI1BC, standing for "Suppressor of KAI1 in Breast Cancer". These results uncover a potential way to harness tumor metastasis via targeting SKAI1BC in human breast cancer, and perhaps also in other KAI1-deficient human malignancies.

Application of the concept synthetic lethality toward anticancer therapy: a promise fulfilled?

Back in 1997, a suggestion to apply the concept of synthetic lethality towards the development of selective, less toxic, cancer drugs and anticancer targets, was brought forward. The availability of large scale synthetic, low-molecular-weight chemical libraries seemed to lend itself to the concept. Human/mouse genome-wide siRNAs and shRNA-expressing libraries allowing high throughput screening for target genes synergistic lethal with defined human cancer aberrations, also raised high hopes of a soon to be established selective therapy. Sixteen years later, the major experimental aspects relating to the implementation of this more focused approach to cancer drug discovery, is briefly and critically reviewed.

Directionality of noncoding human RNAs: how to avoid artifacts.

Inactivation of tumor suppressor and metastasis suppressor genes via epigenetic silencing is a frequent event in human cancers. Recent work has shown new mechanisms of epigenetic silencing, based on the occurrence of long noncoding promoter-spanning antisense and/or sense RNAs (lncRNAs), which constitute part of chromatin silencing complexes. Using reverse transcription polymerase chain reaction (RT-PCR), we have started to scan "triple negative" and Her2-overexpressing breast cancer cell lines for directional/bidirectional transcription through promoters of tumor suppressor and metastasis suppressor genes known to be epigenetically silenced in vivo. Surprisingly, we found that RT-PCR-amplified products were obtained at high frequency in the absence of exogenous primers. These amplified products resulted from RT priming via transcripts originating from promoter or upstream spanning regions. Consequently, this priming overruled directionality determination and led to false detection-identification of such lncRNAs. We show that this prevalent "no primer" artifact can be eliminated by treating the RNA preparations with periodate, performing RT reactions at highly elevated temperatures, or a combination of both. These experimental improvements enabled determination of the presence and directionality of individual promoter-spanning long noncoding RNAs with certainty. Examples for the BRMS1 metastasis suppressor gene, as well as RAR-ß2 and CST6 human tumor suppressor genes, in breast carcinoma cell lines are presented.

ER-alpha-cDNA as part of a bicistronic transcript gives rise to high frequency, long term, receptor expressing cell clones.

Within the large group of Estrogen Receptor alpha (ERα)-negative breast cancer patients, there is a subgroup carrying the phenotype ERα(-), PR(-), and Her2(-), named accordingly "Triple-Negative" (TN). Using cell lines derived from this TN group, we wished to establish cell clones, in which ERα is ectopically expressed, forming part of a synthetic lethality screening system. Initially, we generated cell transfectants expressing a mono-cistronic ERα transcription unit, adjacent to a separate dominant selectable marker transcription unit. However, the yield of ERα expressing colonies was rather low (5-12.5%), and only about half of these displayed stable ectopic ERα expression over time. Generation and maintenance of such cell clones under minimal exposure to the ERα ligand, did not improve yield or expression stability. Indeed, other groups have also reported grave difficulties in obtaining ectopic expression of ERα in ERα-deficient breast carcinoma cells. We therefore switched to transfecting these cell lines with pERα-IRES, a plasmid vector encoding a bicistronic translation mRNA template: ERα Open Reading Frame (ORF) being upstream followed by a dominant-positive selectable marker (hygro(R)) ORF, directed for translation from an Internal Ribosome Entry Site (IRES). Through usage of this bicistronic vector linkage system, it was possible to generate a very high yield of ERα expressing cell clones (50-100%). The stability over time of these clones was also somewhat improved, though variations between individual cell clones were evident. Our successful experience with ERα in this system may serve as a paradigm for other genes where ectopic expression meets similar hardships.

Decoding pooled RNAi screens by means of barcode tiling arrays.

BACKGROUND: RNAi screens via pooled short hairpin RNAs (shRNAs) have recently become a powerful tool for the identification of essential genes in mammalian cells. In the past years, several pooled large-scale shRNA screens have identified a variety of genes involved in cancer cell proliferation. All of those studies employed microarray analysis, utilizing either the shRNA's half hairpin sequence or an additional shRNA-associated 60 nt barcode sequence as a molecular tag. Here we describe a novel method to decode pooled RNAi screens, namely barcode tiling array analysis, and demonstrate how this approach can be used to precisely quantify the abundance of individual shRNAs from a pool. RESULTS: We synthesized DNA microarrays with six overlapping 25 nt long tiling probes complementary to each unique 60 nt molecular barcode sequence associated with every shRNA expression construct. By analyzing dilution series of expression constructs we show how our approach allows quantification of shRNA abundance from a pool and how it clearly outperforms the commonly used analysis via the shRNA's half hairpin sequences. We further demonstrate how barcode tiling arrays can be used to predict anti-proliferative effects of individual shRNAs from pooled negative selection screens. Out of a pool of 305 shRNAs, we identified 28 candidate shRNAs to fully or partially impair the viability of the breast carcinoma cell line MDA-MB-231. Individual validation of a subset of eleven shRNA expression constructs with potential inhibitory, as well as non-inhibitory, effects on the cell line proliferation provides further evidence for the accuracy of the barcode tiling approach. CONCLUSIONS: In summary, we present an improved method for the rapid, quantitative and statistically robust analysis of pooled RNAi screens. Our experimental approach, coupled with commercially available lentiviral vector shRNA libraries, has the potential to greatly facilitate the discovery of putative targets for cancer therapy as well as sensitizers of drug toxicity.

Autophagic and tumour suppressor activity of a novel Beclin1-binding protein UVRAG.

Autophagy, the degradation of cytoplasmic components, is an evolutionarily conserved homeostatic process involved in environmental adaptation, lifespan determination and tumour development. The tumor suppressor Beclin1 is part of the PI(3) kinase class III (PI(3)KC3) lipid-kinase complex that induces autophagy. The autophagic activity of the Beclin1-PI(3)KC3 complex, however, is suppressed by Bcl-2. Here, we report the identification of a novel coiled-coil UV irradiation resistance-associated gene (UVRAG) as a positive regulator of the Beclin1-PI(3)KC3 complex. UVRAG, a tumour suppressor candidate that is monoallelically mutated at high frequency in human colon cancers, associates with the Beclin1-Bcl-2-PI(3)KC3 multiprotein complex, where UVRAG and Beclin1 interdependently induce autophagy. UVRAG-mediated activation of the Beclin1-PI(3)KC3 complex promotes autophagy and also suppresses the proliferation and tumorigenicity of human colon cancer cells. These results identify UVRAG as an essential component of the Beclin1-PI(3)KC3 lipid kinase complex that is an important signalling checkpoint for autophagy and tumour-cell growth.

shRNA-mediated RNA interference as a tool for genetic synthetic lethality screening in mouse embryo fibroblasts.

Previously, we demonstrated the establishment of synthetic lethality screening in cultured somatic human cells, or mouse embryo fibroblasts (MEFs), for chemicals or mutant genes synergistically lethal with a mutated gene of interest. Here, we show in MEFs that the usage of RNA interference-based genetic suppressor elements encoding short hairpin RNAs (shRNAs) enables for genetic synthetic lethality screening at a frequency much higher than that achieved before with short truncated sense and antisense RNAs. These findings open up the possibility of using in mammalian cells genome-wide shRNA libraries for genetic synthetic lethality screening at the multi-gene level.

Replication and episomal maintenance of Epstein-Barr virus-based vectors in mouse embryonal fibroblasts enable synthetic lethality screens.

Recently, we demonstrated the establishment of chemical and genetic synthetic lethality screens in cultured human cells. Here, we report the establishment of this method in mouse embryonal fibroblasts (MEF). The method employs an immortalized mammalian cell line, deficient in a gene of interest, which is complemented by an episomal survival plasmid expressing the wild-type cDNA for the gene of interest and the use of a novel green fluorescent protein (GFP)-based double-label fluorescence system. The crucial part in this endeavor has been the identification of a DNA replicon that could stably replicate in MEFs while under selection for survival and gets spontaneously lost relatively fast in the absence of such a pressure. Here, we show for the first time that EBV-based replicons but not polyoma virus-based ones can replicate and be stably maintained in MEFs. In the chemical screen, selective pressure imposed by synthetic lethal drugs prevented the spontaneous loss of the GFP-marked episome, enabling drug identification. Retention or spontaneous loss over time of the episomal survival plasmid could be sensitively detected in a large-scale blind test in the presence or absence of synthetic lethal chemicals, respectively. Establishing the synthetic lethality screen should thus permit high throughput screening for chemicals, which are synthetically lethal with any mouse mutant/knockout gene of interest. Moreover, it forms the basis for a genetic synthetic lethality screen in MEFs, an important new tool for mouse functional genomics.