Abstract

Natural and synthetic small molecules from the NCI Developmental Therapeutics Program (DTP) were employed in molecular dynamics-based docking with DNA repair proteins whose RNA-Seq based expression was associated with overall cancer survival (OS) after adjustment for the PCNA metagene. The compounds employed were required to elicit a sensitive response (vs. resistance) in more than half of the cell lines tested for each cancer. Methodological approaches included peptide sequence alignments and homology modeling for 3D protein structure determination, ligand preparation, docking, toxicity and ADME prediction. Docking was performed for unique lists of DNA repair proteins which predict OS for AML, cancers of the breast, lung, colon, and ovaries, GBM, melanoma, and renal papillary cancer. Results indicate hundreds of drug-like and lead-like ligands with best-pose binding energies less than −6 kcal/mol. Ligand solubility for the top 20 drug-like hits approached lower bounds, while lipophilicity was acceptable. Most ligands were also blood-brain barrier permeable with high intestinal absorption rates. While the majority of ligands lacked positive prediction for HERG channel blockage and Ames carcinogenicity, there was a considerable variation for predicted fathead minnow, honey bee, and Tetrahymena pyriformis toxicity. The computational results suggest the potential for new targets and mechanisms of repair inhibition and can be directly employed for in vitro and in vivo confirmatory laboratory experiments to identify new targets of therapy for cancer survival.

Highlights

  • One of the hallmarks of cancer is cellular growth dysregulation caused by mutations as a result of genomic instability [1,2]

  • When DNA repair deficiencies occur as a result of oncogenic loss or genetic polymorphisms, alternative DNA repair pathways must be found if replication is to continue [7]

  • In a recent investigation of TCGA RNA-Seq data and DNA repair genes, we identified sets of DNA repair genes for various cancers (Table 1) whose down-regulated expression patterns were associated with prolonged overall survival (OS) [39]

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Summary

Introduction

One of the hallmarks of cancer is cellular growth dysregulation caused by mutations as a result of genomic instability [1,2]. Such mutations play an important role in oncogenic transformation and can be catastrophic during mitosis, or lead to chromothripsis [3,4]. The continuously forced cell division in tumor cells results in replication stress and increased oxidative damage, which requires several DNA repair components [5,6]. When DNA repair deficiencies occur as a result of oncogenic loss or genetic polymorphisms, alternative DNA repair pathways must be found if replication is to continue [7].

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