1O - Suppression of KRAS-G12D and BRAF-V600E oncogene transcription with PNA-conjugates

We have developed a strategy to block transcription of oncogenes such as BRAF V600E and KRAS G12D directly using modified complementary peptide nucleic acid (PNA) oligomers that target oncogenesis specifically causing inhibition of tumour growth. This proof of principle strategy against BRAF V600E and KRAS G12D in vitro and in vivo should provide a new means to develop PNA-delivery peptide conjugates as targeted drug therapeutics across a broad range of oncogenes that drive cancer cell growth. Obstruction of KRAS G12D and BRAF V600E expression was evaluated through suppression of cell proliferation and specific mRNA transcription. Tumour reduction was assessed through Xenograft mouse models. Exposure of KRAS G12D-dependent cell line to modified PNA-peptide conjugate complementary to KRAS G12D mutation sequence also results in concentration-dependent and time-dependent inhibition of cell growth and specific and complete suppression in mRNA transcription. Cell lines expressing KRAS WT and KRAS G12C, both differing by a single nucleobase, show no suppression. Exposure of the melanoma cell lines to a modified PNA-peptide conjugate complementary to BRAF V600E mutation sequence results in a concentration-dependent and time-dependent inhibition of cell growth that is specific for the BRAF V600E mutant melanoma cell lines with inhibition of mRNA and protein expression. Xenograft mouse trials show tumour growth delay and necrosis compared to PNA controls. This 50mg/kg dose was well tolerated without associated weight loss. By H&E staining, tumor tissue from trials shows ablation and extensive scaring upon exposure to BRAF V600E-complementary PNA-peptide conjugate whereas saline and scramble PNA sequence controls do not. Similarly quantitative measurement shows a 2.5-fold decrease in Ki67 and a 3-fold increase in TUNEL expression. Our results indicate that these PNA-peptide derivatives could represent a novel and promising new therapy for patients with genes specific for and causative of tumorigenesis. This strategy could be applied to a multitude of cancers either with specific translocations or mutations differing from wild-type cells even by only a single base pair. The authors. Celgene, Fortress Biotech. All authors have declared no conflicts of interest.