PREVENTING THE CHROMOSOMAL TRANSLOCATIONS THAT CAUSE CANCER

Overview

Journal Trans Am Clin Climatol Assoc

Specialty Rehabilitation Medicine

Date 2017 Jan 10

PMID 28066052

Citations 9

Authors

Robert Hromas

Elizabeth Williamson

Suk-Hee Lee

Jac Nickoloff

Affiliations

Soon will be listed here.

Abstract

Approximately half of all cancers harbor chromosomal translocations that can either contribute to their origin or govern their subsequent behavior. Chromosomal translocations by definition can only occur when there are two DNA double-strand breaks (DSBs) on distinct chromosomes that are repaired heterologously. Thus, chromosomal translocations are by their very nature problems of DNA DSB repair. Such DNA DSBs can be from internal or external sources. Internal sources of DNA DSBs that can lead to translocations can occur are inappropriate immune receptor gene maturation during V(D)J recombination or heavy-chain switching. Other internal DNA DSBs can come from aberrant DNA structures, or are generated at collapsed and reversed replication forks. External sources of DNA DSBs that can generate chromosomal translocations are ionizing radiation and cancer chemotherapy. There are several known nuclear and chromatin properties that enhance translocations over homologous chromosome DSB repair. The proximity of the region of the heterologous chromosomes to each other increases translocation rates. Histone methylation events at the DSB also influence translocation frequencies. There are four DNA DSB repair pathways, but it appears that only one, alternative non-homologous end-joining (a-NHEJ) can mediate chromosomal translocations. The rate-limiting, initial step of a-NHEJ is the binding of poly-adenosine diphosphate ribose polymerase 1 (PARP1) to the DSB. In our investigation of methods for preventing oncogenic translocations, we discovered that PARP1 was required for translocations. Significantly, the clinically approved PARP1 inhibitors can block the formation of chromosomal translocations, raising the possibility for the first time that secondary oncogenic translocations can be reduced in high risk patients.

Citing Articles

Cellular Responses to Widespread DNA Replication Stress.

Nickoloff J, Jaiswal A, Sharma N, Williamson E, Tran M, Arris D Int J Mol Sci. 2023; 24(23).

PMID: 38069223 PMC: 10707325. DOI: 10.3390/ijms242316903.

Role of the mechanisms for antibody repertoire diversification in monoclonal light chain deposition disorders: when a friend becomes foe.

Del Pozo-Yauner L, Herrera G, Perez Carreon J, Turbat-Herrera E, Rodriguez-Alvarez F, Ruiz Zamora R Front Immunol. 2023; 14:1203425.

PMID: 37520549 PMC: 10374031. DOI: 10.3389/fimmu.2023.1203425.

Metnase and EEPD1: DNA Repair Functions and Potential Targets in Cancer Therapy.

Nickoloff J, Sharma N, Taylor L, Allen S, Lee S, Hromas R Front Oncol. 2022; 12:808757.

PMID: 35155245 PMC: 8831698. DOI: 10.3389/fonc.2022.808757.

Lack of associations between gene polymorphisms and neuroblastoma susceptibility in Chinese children.

Cheng J, Wei K, Xin Y, Zhao P, Zhang J, Jia W J Cancer. 2019; 10(23):5722-5726.

PMID: 31737108 PMC: 6843871. DOI: 10.7150/jca.33605.

Frequent homozygous deletions of the CDKN2A locus in somatic cancer tissues.

Hamid A, Petreaca B, Petreaca R Mutat Res. 2019; 815:30-40.

PMID: 31096160 PMC: 8026102. DOI: 10.1016/j.mrfmmm.2019.04.002.

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