Genome scale molecular analysis has revolutionized the experimental process by which the genes and pathways that influence the initiation, progression, and treatment of cancer can be identified. This has opened up many exciting avenues of biomedical research, but it has also served to confirm the genetic and cellular complexity that underlies tumorigenesis. The identification of the gene silencing mechanism, RNA interference (RNAi), initially in invertebrates and later in mammalian cells, has had enormous implications for our understanding of the regulation of gene expression and our ability to modulate it experimentally. This project is focused on the hypothesis that molecular and phenotypic perturbations induced by RNAi will give insight into the biology of cancer and identify novel anti-cancer molecular targets. The intention of most studies exploiting the RNAi mechanism for loss of function (LOF) analysis is the gene-specific cleavage of protein encoding mRNAs. Technologies that exploit the endogenous RNA-based gene silencing mechanism, RNAi, have developed rapidly for the dissection of gene-function relationships and as a means of furthering molecular target analysis. The overall goal of this project is the enhanced application of RNAi-based technologies for the study of cancer biology. To do this we are focusing on establishing protocols and assays for the reproducible assessment of the effects of RNAi at a molecular and functional level that can be used in mammalian cell line model systems appropriate for the study of tumorigenesis. We are applying optimized and robust protocols for inducing RNAi in cells using synthetic siRNAs and other RNAi effectors, such as short hairpin RNAs (shRNAs) and the use of quantitative assays for analyzing the efficacy of RNA. To date we have examined the silencing mediated by siRNAs corresponding to over ≈250 human genes and ≈150 shRNA clones corresponding to ≈50 human genes (this latter study was originally detailed under project number Z01 BC 010614 but this work has now been aligned within this project effort). This project continues to be critical for assisting and training CCR Investigators in the application of RNAi analysis, and for the establishment of protocols for RNAi screens targeting hundreds of human genes (see Z01 BC 010615).
Zhang, Yong-Wei; Jones, Tamara L; Martin, Scott E et al. (2009) Implication of checkpoint kinase-dependent up-regulation of ribonucleotide reductase R2 in DNA damage response. J Biol Chem 284:18085-95 |
Klootwijk, Riko D; Savelkoul, Paul J M; Ciccone, Carla et al. (2008) Allele-specific silencing of the dominant disease allele in sialuria by RNA interference. FASEB J 22:3846-52 |
Martin, Scott E; Jones, Tamara L; Thomas, Cheryl L et al. (2007) Multiplexing siRNAs to compress RNAi-based screen size in human cells. Nucleic Acids Res 35:e57 |
Martin, Scott E; Caplen, Natasha J (2007) Applications of RNA interference in mammalian systems. Annu Rev Genomics Hum Genet 8:81-108 |
Ludwig, Joseph A; Szakacs, Gergely; Martin, Scott E et al. (2006) Selective toxicity of NSC73306 in MDR1-positive cells as a new strategy to circumvent multidrug resistance in cancer. Cancer Res 66:4808-15 |