Go beyond BRCA 1/2, DNA Damage Response
Oncology

Go beyond BRCA 1/2

Expand your biomarker coverage

Germline pathogenic variants in DNA damage response (DDR) genes have garnered increasing attention in many cancers including breast, ovarian, prostate and pancreatic1,2,3. NGS offers growing opportunities to characterize DDR targets, with important implications for targeted therapies in the future. However, the demand for specialized resources for complex workflows and bioinformatics is a daunting challenge. Our panels overcome such limitations to expand your DDR biomarker coverage beyond BRCA1/2.

DDR and cancer development9
The root cause of genomic instability

Everyday the human DNA is bombarded with numerous DNA damaging events4,5. Different cellular signaling events and enzymatic activities are triggered to repair these DNA damage. The events are collectively known as the DNA damage response (DDR). There are two types of DDR:

  • Functional DDR: Rapid and efficient repair of DNA damage through cell cycle arrests or apoptosis. Functional DDR helps to maintain genomic integrity, which is critical for cell survival and viability2,6,7
  • Dysfunctional DDR: Mutations and/or dysregulation of DDR mechanisms lead to unrepaired DNA damage disrupting genomic integrity. The genomic instability induces various aberrant cellular behaviors leading to the development of cancer.
DDR is dependent on the type of DNA damage

For each type of DNA damage, the cell has evolved a specific pathway for repair that typically involves many proteins. Various proteins involved in the DNA repair pathway include PARP enzymes in BER, NER proteins in NER and MMR enzymes in MMR pathway6,7,8.

Homologous recombination repair (HRR) proteins repair the double strand breaks (DSBs) in DNA. BRCA1 and BRCA2 are tumor suppressor proteins that are well characterized members of the HRR pathway9. Loss of function or deleterious mutations in HRR genes contribute to homologous repair deficiency (HRD).

Types of DNA damage and repair mechanisms 
Explore our DDR solutions
Discover QIAseq HRR panels to confidently detect DDR biomarkers.
View Products

Discover
DNA damage response solutions

Female scientist working on a computer in a laboratory
Learn about our QIAseq HRR Panel

The QIAseq HRR Panel allows you to identify relevant biomarker of the HRR pathway beyond BRCA1 and BRCA2. Interested in additional information?

Read About it
QIAGEN is part of the Friends of Cancer Research (FOCR) initiative to harmonize HRR testing globally.

Featured success story

Nils Hartmann, webinar speaker, customer portrait, Clinical genomics, HRR, Oncology

 

"I was able to easily customize the QIAseq HRR Panel for the detection of HRR genes."

Dr. Nils Hartmann, Mainz University Medical Center, Germany

Watch webinar
QIAseq HRR Panel drives new biomarker insights in multiple HR deficient cancers

Are you interested in valuable NGS insights? Want a streamlined NGS solution that you can customize? Don't look any further. Our QIAseq HRR Panel is flexible to meet your every NGS need. You will be able to customize your panel by adding your genes of interest. Dr. Nils Hartmann illustrates the benefit of the custom QIAseq panel and pre-optimized analystics workflow in th profiling of genetic alterations in breast, ovarian and prostate cancers.

References
  1. Hakem, R. (2008) DNA-damage repair; the good, the bad, and the ugly. The EMBO Journal, 27, 589–605.
  2. Nowsheen, S. and Yang, E.S. (2012) The intersection between DNA damage response and cell death pathways. Exp. Oncol. 34(3), 243-254.
  3. Ubhi, T. and Brown, G. (2019) Exploiting DNA Replication Stress for Cancer Treatment. Cancer Res. 79(8),1730-1739.
  4. Ciccia, A. and Stephen, G. (2010) The DNA Damage Response: Making it Safe to Play with Knives. Mol. Cell 40(2),179-204.
  5. Jackson, S. and Bartek, J. (2009) The DNA-damage response in human biology and disease. Nature 461(7267),1071-1078
  6. Hirsch, S., Gieldon, L. Sutter, C., Dikow, N., Schaaf, C. (2021) Germline testing for homologous recombination repair genes-opportunities and challenges. Genes Chromosom. Cancer 60(5), 332-343
  7. Francis, M., Barnieh, M., Robert, L., Falconer, A. (2021) Progress towards a clinically-successful ATR inhibitor for cancer therapy. Curr. Res. in Pharmacol. and Drug Discov. 2,100017
  8. Heeke, A. et.al. (2018) Prevalence of Homologous Recombination–Related Gene Mutations Across Multiple Cancer Types. JCO Precis. Oncol. 2: PO.17.00286.
  9. Samstein, R. and Riaz, N. (2018) The DNA damage response in immunotherapy and radiation. Adv. in Rad. Oncol. 3(4), 527-533.

The products mentioned here are intended for molecular biology applications. These products are not intended for the diagnosis, prevention, or treatment of a disease.