Abstract

Genomic instability can be observed at both chromosomal and chromatin levels. Instability at the macro level includes centrosome abnormalities (CA) resulting in numerical as well as structural chromosomal changes, whereas instability at the micro level is characterized by defects in DNA repair pathways resulting in microsatellite instability (MIN) or mutations. Genomic instability occurs during carcinogenesis without impairing survival and growth, though the precise mechanisms remain unclear. Solid tumors arising from most cells of epithelial origin are characterized by genomic instability which renders them resistant to chemotherapy and radiotherapy. This instability is also observed in 25% of myeloma patients and has been shown to be highly prognostic, independently of the international staging system (ISS). However, a biomarker of aberrant DNA repair and loss of heterozygosity (LOH), was only observed at a frequency of 5% in newly diagnosed patients. Several new molecules targeting the pathways involved in genomic instability are under development and some have already entered clinical trials. Poly(ADP-ribose) polymerase-1 (PARP) inhibitors have been FDA-approved for the treatment of breast cancer type 1 susceptibility protein (BRCA1)-mutated metastatic breast cancer, as well as ovarian and lung cancer. Topoisomerase inhibitors and epigenetic histone modification-targeting inhibitors, such as HDAC (Histone Deacetylase) inhibitors which are novel agents that can target genomic instability. Several of the small molecule inhibitors targeting chromosomal level instability such as PARP, Akt, Aurora kinase, cyclin dependent kinase or spindle kinase inhibitors have been tested in mouse models and early phase I/II trials. ATM, ATR kinase inhibitors and DNA helicase inhibitors are also promising novel agents. However, most of these drugs are not effective as single agents but appear to act synergistically with DNA damaging agents such as radiotherapy, platinum derivatives, immunomodulators, and proteasome inhibitors. In this review, new drugs targeting genomic instability and their mechanisms of action will be discussed.

Highlights

  • The 2015 Nobel Prize in chemistry was awarded to three scientists – Paul Modrich, Aziz Sancar and Thomas Lindahl, for their seminal studies into the mechanisms of DNA repair

  • Further studies are ongoing to determine the maximal tolerable dose (MTD) of the different drugs in this regimen. Alkylating agents such as busulfan used in transplant conditioning regimens, impair replication forks by DNA strand cross-linking, Neri et al hypothesized that Poly(ADP-ribose) polymerase-1 (PARP) inhibition with veliparib in combination with busulfan might lead to synergistic cytotoxicity against tumor cells in a xenotransplant model of myeloproliferative disease

  • This study demonstrated the preliminary anti-MM activity of Alisertib in refractory MM (RRMM) patients and non-Hodgkin Lymphoma (Kelly et al, 2014)

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Summary

Drug Targeting of Genomic Instability in Multiple Myeloma

Specialty section: This article was submitted to Cancer Genetics, a section of the journal

Frontiers in Genetics
INTRODUCTION
PROGNOSTIC ROLE OF DNA REPAIR DEFECTS AND GENOMIC INSTABILITY
TARGETING DNA REPAIR DEFECTS
Drugs Veliparib
Cyclin Dependent Kinase Inhibitors
Antisense Oligomers
Spindle Assembly Checkpoint and Microtubule Inhibitors
NER Inhibition
Telomerase Inhibitors
Findings
CONCLUSION

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